/* gspawn.c - Process launching
 *
 *  Copyright 2000 Red Hat, Inc.
 *  g_execvpe implementation based on GNU libc execvp:
 *   Copyright 1991, 92, 95, 96, 97, 98, 99 Free Software Foundation, Inc.
 *
 * SPDX-License-Identifier: LGPL-2.1-or-later
 *
 * This library is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public
 * License as published by the Free Software Foundation; either
 * version 2.1 of the License, or (at your option) any later version.
 *
 * This library is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General Public License
 * along with this library; if not, see <http://www.gnu.org/licenses/>.
 */

#include "config.h"

#include <sys/time.h>
#include <sys/types.h>
#include <sys/wait.h>
#include <unistd.h>
#include <errno.h>
#include <fcntl.h>
#include <signal.h>
#include <string.h>
#include <stdlib.h>   /* for fdwalk */
#include <dirent.h>
#include <unistd.h>

#ifdef HAVE_SPAWN_H
#include <spawn.h>
#endif /* HAVE_SPAWN_H */

#ifdef HAVE_CRT_EXTERNS_H
#include <crt_externs.h> /* for _NSGetEnviron */
#endif

#ifdef HAVE_SYS_SELECT_H
#include <sys/select.h>
#endif /* HAVE_SYS_SELECT_H */

#ifdef HAVE_SYS_RESOURCE_H
#include <sys/resource.h>
#endif /* HAVE_SYS_RESOURCE_H */

#if defined(__linux__) || defined(__DragonFly__)
#include <sys/syscall.h>  /* for syscall and SYS_getdents64 */
#endif

#include "gspawn.h"
#include "gspawn-private.h"
#include "gthread.h"
#include "gtrace-private.h"
#include "glib/gstdio.h"

#include "genviron.h"
#include "gmem.h"
#include "gshell.h"
#include "gstring.h"
#include "gstrfuncs.h"
#include "gtestutils.h"
#include "gutils.h"
#include "glibintl.h"
#include "glib-unix.h"

#ifdef __APPLE__
#include <libproc.h>
#include <sys/proc_info.h>
#endif

#define INHERITS_OR_NULL_STDIN  (G_SPAWN_STDIN_FROM_DEV_NULL | G_SPAWN_CHILD_INHERITS_STDIN)
#define INHERITS_OR_NULL_STDOUT (G_SPAWN_STDOUT_TO_DEV_NULL | G_SPAWN_CHILD_INHERITS_STDOUT)
#define INHERITS_OR_NULL_STDERR (G_SPAWN_STDERR_TO_DEV_NULL | G_SPAWN_CHILD_INHERITS_STDERR)

#define IS_STD_FILENO(_fd) ((_fd >= STDIN_FILENO) && (_fd <= STDERR_FILENO))
#define IS_VALID_FILENO(_fd) (_fd >= 0)

/* posix_spawn() is assumed the fastest way to spawn, but glibc's
 * implementation was buggy before glibc 2.24, so avoid it on old versions.
 */
#ifdef HAVE_POSIX_SPAWN
#ifdef __GLIBC__

#if __GLIBC_PREREQ(2,24)
#define POSIX_SPAWN_AVAILABLE
#endif

#else /* !__GLIBC__ */
/* Assume that all non-glibc posix_spawn implementations are fine. */
#define POSIX_SPAWN_AVAILABLE
#endif /* __GLIBC__ */
#endif /* HAVE_POSIX_SPAWN */

#ifdef HAVE__NSGETENVIRON
#define environ (*_NSGetEnviron())
#else
extern char **environ;
#endif

#ifndef O_CLOEXEC
#define O_CLOEXEC 0
#else
#define HAVE_O_CLOEXEC 1
#endif

/**
 * SECTION:spawn
 * @Short_description: process launching
 * @Title: Spawning Processes
 *
 * GLib supports spawning of processes with an API that is more
 * convenient than the bare UNIX fork() and exec().
 *
 * The g_spawn family of functions has synchronous (g_spawn_sync())
 * and asynchronous variants (g_spawn_async(), g_spawn_async_with_pipes()),
 * as well as convenience variants that take a complete shell-like
 * commandline (g_spawn_command_line_sync(), g_spawn_command_line_async()).
 *
 * See #GSubprocess in GIO for a higher-level API that provides
 * stream interfaces for communication with child processes.
 *
 * An example of using g_spawn_async_with_pipes():
 * |[<!-- language="C" -->
 * const gchar * const argv[] = { "my-favourite-program", "--args", NULL };
 * gint child_stdout, child_stderr;
 * GPid child_pid;
 * g_autoptr(GError) error = NULL;
 *
 * // Spawn child process.
 * g_spawn_async_with_pipes (NULL, argv, NULL, G_SPAWN_DO_NOT_REAP_CHILD, NULL,
 *                           NULL, &child_pid, NULL, &child_stdout,
 *                           &child_stderr, &error);
 * if (error != NULL)
 *   {
 *     g_error ("Spawning child failed: %s", error->message);
 *     return;
 *   }
 *
 * // Add a child watch function which will be called when the child process
 * // exits.
 * g_child_watch_add (child_pid, child_watch_cb, NULL);
 *
 * // You could watch for output on @child_stdout and @child_stderr using
 * // #GUnixInputStream or #GIOChannel here.
 *
 * static void
 * child_watch_cb (GPid     pid,
 *                 gint     status,
 *                 gpointer user_data)
 * {
 *   g_message ("Child %" G_PID_FORMAT " exited %s", pid,
 *              g_spawn_check_wait_status (status, NULL) ? "normally" : "abnormally");
 *
 *   // Free any resources associated with the child here, such as I/O channels
 *   // on its stdout and stderr FDs. If you have no code to put in the
 *   // child_watch_cb() callback, you can remove it and the g_child_watch_add()
 *   // call, but you must also remove the G_SPAWN_DO_NOT_REAP_CHILD flag,
 *   // otherwise the child process will stay around as a zombie until this
 *   // process exits.
 *
 *   g_spawn_close_pid (pid);
 * }
 * ]|
 */


static gint g_execute (const gchar  *file,
                       gchar       **argv,
                       gchar       **argv_buffer,
                       gsize         argv_buffer_len,
                       gchar       **envp,
                       const gchar  *search_path,
                       gchar        *search_path_buffer,
                       gsize         search_path_buffer_len);

static gboolean fork_exec (gboolean              intermediate_child,
                           const gchar          *working_directory,
                           const gchar * const  *argv,
                           const gchar * const  *envp,
                           gboolean              close_descriptors,
                           gboolean              search_path,
                           gboolean              search_path_from_envp,
                           gboolean              stdout_to_null,
                           gboolean              stderr_to_null,
                           gboolean              child_inherits_stdin,
                           gboolean              file_and_argv_zero,
                           gboolean              cloexec_pipes,
                           GSpawnChildSetupFunc  child_setup,
                           gpointer              user_data,
                           GPid                 *child_pid,
                           gint                 *stdin_pipe_out,
                           gint                 *stdout_pipe_out,
                           gint                 *stderr_pipe_out,
                           gint                  stdin_fd,
                           gint                  stdout_fd,
                           gint                  stderr_fd,
                           const gint           *source_fds,
                           const gint           *target_fds,
                           gsize                 n_fds,
                           GError              **error);

G_DEFINE_QUARK (g-exec-error-quark, g_spawn_error)
G_DEFINE_QUARK (g-spawn-exit-error-quark, g_spawn_exit_error)

/**
 * g_spawn_async:
 * @working_directory: (type filename) (nullable): child's current working
 *     directory, or %NULL to inherit parent's
 * @argv: (array zero-terminated=1) (element-type filename):
 *     child's argument vector
 * @envp: (array zero-terminated=1) (element-type filename) (nullable):
 *     child's environment, or %NULL to inherit parent's
 * @flags: flags from #GSpawnFlags
 * @child_setup: (scope async) (closure user_data) (nullable): function to run
 *     in the child just before `exec()`
 * @user_data: user data for @child_setup
 * @child_pid: (out) (optional): return location for child process reference, or %NULL
 * @error: return location for error
 *
 * Executes a child program asynchronously.
 * 
 * See g_spawn_async_with_pipes() for a full description; this function
 * simply calls the g_spawn_async_with_pipes() without any pipes.
 *
 * You should call g_spawn_close_pid() on the returned child process
 * reference when you don't need it any more.
 * 
 * If you are writing a GTK application, and the program you are spawning is a
 * graphical application too, then to ensure that the spawned program opens its
 * windows on the right screen, you may want to use #GdkAppLaunchContext,
 * #GAppLaunchContext, or set the %DISPLAY environment variable.
 *
 * Note that the returned @child_pid on Windows is a handle to the child
 * process and not its identifier. Process handles and process identifiers
 * are different concepts on Windows.
 *
 * Returns: %TRUE on success, %FALSE if error is set
 **/
gboolean
g_spawn_async (const gchar          *working_directory,
               gchar               **argv,
               gchar               **envp,
               GSpawnFlags           flags,
               GSpawnChildSetupFunc  child_setup,
               gpointer              user_data,
               GPid                 *child_pid,
               GError              **error)
{
  return g_spawn_async_with_pipes (working_directory,
                                   argv, envp,
                                   flags,
                                   child_setup,
                                   user_data,
                                   child_pid,
                                   NULL, NULL, NULL,
                                   error);
}

/* Avoids a danger in threaded situations (calling close()
 * on a file descriptor twice, and another thread has
 * re-opened it since the first close)
 *
 * This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)).
 */
static void
close_and_invalidate (gint *fd)
{
  if (*fd < 0)
    return;

  g_close (*fd, NULL);
  *fd = -1;
}

/* Some versions of OS X define READ_OK in public headers */
#undef READ_OK

typedef enum
{
  READ_FAILED = 0, /* FALSE */
  READ_OK,
  READ_EOF
} ReadResult;

static ReadResult
read_data (GString *str,
           gint     fd,
           GError **error)
{
  gssize bytes;
  gchar buf[4096];

 again:
  bytes = read (fd, buf, 4096);

  if (bytes == 0)
    return READ_EOF;
  else if (bytes > 0)
    {
      g_string_append_len (str, buf, bytes);
      return READ_OK;
    }
  else if (errno == EINTR)
    goto again;
  else
    {
      int errsv = errno;

      g_set_error (error,
                   G_SPAWN_ERROR,
                   G_SPAWN_ERROR_READ,
                   _("Failed to read data from child process (%s)"),
                   g_strerror (errsv));

      return READ_FAILED;
    }
}

/**
 * g_spawn_sync:
 * @working_directory: (type filename) (nullable): child's current working
 *     directory, or %NULL to inherit parent's
 * @argv: (array zero-terminated=1) (element-type filename):
 *     child's argument vector, which must be non-empty and %NULL-terminated
 * @envp: (array zero-terminated=1) (element-type filename) (nullable):
 *     child's environment, or %NULL to inherit parent's
 * @flags: flags from #GSpawnFlags
 * @child_setup: (scope call) (closure user_data) (nullable): function to run
 *     in the child just before `exec()`
 * @user_data: user data for @child_setup
 * @standard_output: (out) (array zero-terminated=1) (element-type guint8) (optional): return location for child output, or %NULL
 * @standard_error: (out) (array zero-terminated=1) (element-type guint8) (optional): return location for child error messages, or %NULL
 * @wait_status: (out) (optional): return location for child wait status, as returned by waitpid(), or %NULL
 * @error: return location for error, or %NULL
 *
 * Executes a child synchronously (waits for the child to exit before returning).
 *
 * All output from the child is stored in @standard_output and @standard_error,
 * if those parameters are non-%NULL. Note that you must set the  
 * %G_SPAWN_STDOUT_TO_DEV_NULL and %G_SPAWN_STDERR_TO_DEV_NULL flags when
 * passing %NULL for @standard_output and @standard_error.
 *
 * If @wait_status is non-%NULL, the platform-specific status of
 * the child is stored there; see the documentation of
 * g_spawn_check_wait_status() for how to use and interpret this.
 * On Unix platforms, note that it is usually not equal
 * to the integer passed to `exit()` or returned from `main()`.
 *
 * Note that it is invalid to pass %G_SPAWN_DO_NOT_REAP_CHILD in
 * @flags, and on POSIX platforms, the same restrictions as for
 * g_child_watch_source_new() apply.
 *
 * If an error occurs, no data is returned in @standard_output,
 * @standard_error, or @wait_status.
 *
 * This function calls g_spawn_async_with_pipes() internally; see that
 * function for full details on the other parameters and details on
 * how these functions work on Windows.
 * 
 * Returns: %TRUE on success, %FALSE if an error was set
 */
gboolean
g_spawn_sync (const gchar          *working_directory,
              gchar               **argv,
              gchar               **envp,
              GSpawnFlags           flags,
              GSpawnChildSetupFunc  child_setup,
              gpointer              user_data,
              gchar               **standard_output,
              gchar               **standard_error,
              gint                 *wait_status,
              GError              **error)     
{
  gint outpipe = -1;
  gint errpipe = -1;
  GPid pid;
  gint ret;
  GString *outstr = NULL;
  GString *errstr = NULL;
  gboolean failed;
  gint status;
  
  g_return_val_if_fail (argv != NULL, FALSE);
  g_return_val_if_fail (argv[0] != NULL, FALSE);
  g_return_val_if_fail (!(flags & G_SPAWN_DO_NOT_REAP_CHILD), FALSE);
  g_return_val_if_fail (standard_output == NULL ||
                        !(flags & G_SPAWN_STDOUT_TO_DEV_NULL), FALSE);
  g_return_val_if_fail (standard_error == NULL ||
                        !(flags & G_SPAWN_STDERR_TO_DEV_NULL), FALSE);
  
  /* Just to ensure segfaults if callers try to use
   * these when an error is reported.
   */
  if (standard_output)
    *standard_output = NULL;

  if (standard_error)
    *standard_error = NULL;
  
  if (!fork_exec (FALSE,
                  working_directory,
                  (const gchar * const *) argv,
                  (const gchar * const *) envp,
                  !(flags & G_SPAWN_LEAVE_DESCRIPTORS_OPEN),
                  (flags & G_SPAWN_SEARCH_PATH) != 0,
                  (flags & G_SPAWN_SEARCH_PATH_FROM_ENVP) != 0,
                  (flags & G_SPAWN_STDOUT_TO_DEV_NULL) != 0,
                  (flags & G_SPAWN_STDERR_TO_DEV_NULL) != 0,
                  (flags & G_SPAWN_CHILD_INHERITS_STDIN) != 0,
                  (flags & G_SPAWN_FILE_AND_ARGV_ZERO) != 0,
                  (flags & G_SPAWN_CLOEXEC_PIPES) != 0,
                  child_setup,
                  user_data,
                  &pid,
                  NULL,
                  standard_output ? &outpipe : NULL,
                  standard_error ? &errpipe : NULL,
                  -1, -1, -1,
                  NULL, NULL, 0,
                  error))
    return FALSE;

  /* Read data from child. */
  
  failed = FALSE;

  if (outpipe >= 0)
    {
      outstr = g_string_new (NULL);
    }
      
  if (errpipe >= 0)
    {
      errstr = g_string_new (NULL);
    }

  /* Read data until we get EOF on both pipes. */
  while (!failed &&
         (outpipe >= 0 ||
          errpipe >= 0))
    {
      /* Any negative FD in the array is ignored, so we can use a fixed length.
       * We can use UNIX FDs here without worrying about Windows HANDLEs because
       * the Windows implementation is entirely in gspawn-win32.c. */
      GPollFD fds[] =
        {
          { outpipe, G_IO_IN | G_IO_HUP | G_IO_ERR, 0 },
          { errpipe, G_IO_IN | G_IO_HUP | G_IO_ERR, 0 },
        };

      ret = g_poll (fds, G_N_ELEMENTS (fds), -1  /* no timeout */);

      if (ret < 0)
        {
          int errsv = errno;

	  if (errno == EINTR)
	    continue;

          failed = TRUE;

          g_set_error (error,
                       G_SPAWN_ERROR,
                       G_SPAWN_ERROR_READ,
                       _("Unexpected error in reading data from a child process (%s)"),
                       g_strerror (errsv));
              
          break;
        }

      if (outpipe >= 0 && fds[0].revents != 0)
        {
          switch (read_data (outstr, outpipe, error))
            {
            case READ_FAILED:
              failed = TRUE;
              break;
            case READ_EOF:
              close_and_invalidate (&outpipe);
              outpipe = -1;
              break;
            default:
              break;
            }

          if (failed)
            break;
        }

      if (errpipe >= 0 && fds[1].revents != 0)
        {
          switch (read_data (errstr, errpipe, error))
            {
            case READ_FAILED:
              failed = TRUE;
              break;
            case READ_EOF:
              close_and_invalidate (&errpipe);
              errpipe = -1;
              break;
            default:
              break;
            }

          if (failed)
            break;
        }
    }

  /* These should only be open still if we had an error.  */
  
  if (outpipe >= 0)
    close_and_invalidate (&outpipe);
  if (errpipe >= 0)
    close_and_invalidate (&errpipe);
  
  /* Wait for child to exit, even if we have
   * an error pending.
   */
 again:
      
  ret = waitpid (pid, &status, 0);

  if (ret < 0)
    {
      if (errno == EINTR)
        goto again;
      else if (errno == ECHILD)
        {
          if (wait_status)
            {
              g_warning ("In call to g_spawn_sync(), wait status of a child process was requested but ECHILD was received by waitpid(). See the documentation of g_child_watch_source_new() for possible causes.");
            }
          else
            {
              /* We don't need the wait status. */
            }
        }
      else
        {
          if (!failed) /* avoid error pileups */
            {
              int errsv = errno;

              failed = TRUE;
                  
              g_set_error (error,
                           G_SPAWN_ERROR,
                           G_SPAWN_ERROR_READ,
                           _("Unexpected error in waitpid() (%s)"),
                           g_strerror (errsv));
            }
        }
    }
  
  if (failed)
    {
      if (outstr)
        g_string_free (outstr, TRUE);
      if (errstr)
        g_string_free (errstr, TRUE);

      return FALSE;
    }
  else
    {
      if (wait_status)
        *wait_status = status;
      
      if (standard_output)        
        *standard_output = g_string_free (outstr, FALSE);

      if (standard_error)
        *standard_error = g_string_free (errstr, FALSE);

      return TRUE;
    }
}

/**
 * g_spawn_async_with_pipes:
 * @working_directory: (type filename) (nullable): child's current working
 *     directory, or %NULL to inherit parent's, in the GLib file name encoding
 * @argv: (array zero-terminated=1) (element-type filename): child's argument
 *     vector, in the GLib file name encoding; it must be non-empty and %NULL-terminated
 * @envp: (array zero-terminated=1) (element-type filename) (nullable):
 *     child's environment, or %NULL to inherit parent's, in the GLib file
 *     name encoding
 * @flags: flags from #GSpawnFlags
 * @child_setup: (scope async) (closure user_data) (nullable): function to run
 *     in the child just before `exec()`
 * @user_data: user data for @child_setup
 * @child_pid: (out) (optional): return location for child process ID, or %NULL
 * @standard_input: (out) (optional): return location for file descriptor to write to child's stdin, or %NULL
 * @standard_output: (out) (optional): return location for file descriptor to read child's stdout, or %NULL
 * @standard_error: (out) (optional): return location for file descriptor to read child's stderr, or %NULL
 * @error: return location for error
 *
 * Identical to g_spawn_async_with_pipes_and_fds() but with `n_fds` set to zero,
 * so no FD assignments are used.
 *
 * Returns: %TRUE on success, %FALSE if an error was set
 */
gboolean
g_spawn_async_with_pipes (const gchar          *working_directory,
                          gchar               **argv,
                          gchar               **envp,
                          GSpawnFlags           flags,
                          GSpawnChildSetupFunc  child_setup,
                          gpointer              user_data,
                          GPid                 *child_pid,
                          gint                 *standard_input,
                          gint                 *standard_output,
                          gint                 *standard_error,
                          GError              **error)
{
  return g_spawn_async_with_pipes_and_fds (working_directory,
                                           (const gchar * const *) argv,
                                           (const gchar * const *) envp,
                                           flags,
                                           child_setup, user_data,
                                           -1, -1, -1,
                                           NULL, NULL, 0,
                                           child_pid,
                                           standard_input,
                                           standard_output,
                                           standard_error,
                                           error);
}

/**
 * g_spawn_async_with_pipes_and_fds:
 * @working_directory: (type filename) (nullable): child's current working
 *     directory, or %NULL to inherit parent's, in the GLib file name encoding
 * @argv: (array zero-terminated=1) (element-type filename): child's argument
 *     vector, in the GLib file name encoding; it must be non-empty and %NULL-terminated
 * @envp: (array zero-terminated=1) (element-type filename) (nullable):
 *     child's environment, or %NULL to inherit parent's, in the GLib file
 *     name encoding
 * @flags: flags from #GSpawnFlags
 * @child_setup: (scope async) (closure user_data) (nullable): function to run
 *     in the child just before `exec()`
 * @user_data: user data for @child_setup
 * @stdin_fd: file descriptor to use for child's stdin, or `-1`
 * @stdout_fd: file descriptor to use for child's stdout, or `-1`
 * @stderr_fd: file descriptor to use for child's stderr, or `-1`
 * @source_fds: (array length=n_fds) (nullable): array of FDs from the parent
 *    process to make available in the child process
 * @target_fds: (array length=n_fds) (nullable): array of FDs to remap
 *    @source_fds to in the child process
 * @n_fds: number of FDs in @source_fds and @target_fds
 * @child_pid_out: (out) (optional): return location for child process ID, or %NULL
 * @stdin_pipe_out: (out) (optional): return location for file descriptor to write to child's stdin, or %NULL
 * @stdout_pipe_out: (out) (optional): return location for file descriptor to read child's stdout, or %NULL
 * @stderr_pipe_out: (out) (optional): return location for file descriptor to read child's stderr, or %NULL
 * @error: return location for error
 *
 * Executes a child program asynchronously (your program will not
 * block waiting for the child to exit).
 *
 * The child program is specified by the only argument that must be
 * provided, @argv. @argv should be a %NULL-terminated array of strings,
 * to be passed as the argument vector for the child. The first string
 * in @argv is of course the name of the program to execute. By default,
 * the name of the program must be a full path. If @flags contains the
 * %G_SPAWN_SEARCH_PATH flag, the `PATH` environment variable is used to
 * search for the executable. If @flags contains the
 * %G_SPAWN_SEARCH_PATH_FROM_ENVP flag, the `PATH` variable from @envp
 * is used to search for the executable. If both the
 * %G_SPAWN_SEARCH_PATH and %G_SPAWN_SEARCH_PATH_FROM_ENVP flags are
 * set, the `PATH` variable from @envp takes precedence over the
 * environment variable.
 *
 * If the program name is not a full path and %G_SPAWN_SEARCH_PATH flag
 * is not used, then the program will be run from the current directory
 * (or @working_directory, if specified); this might be unexpected or even
 * dangerous in some cases when the current directory is world-writable.
 *
 * On Windows, note that all the string or string vector arguments to
 * this function and the other `g_spawn*()` functions are in UTF-8, the
 * GLib file name encoding. Unicode characters that are not part of
 * the system codepage passed in these arguments will be correctly
 * available in the spawned program only if it uses wide character API
 * to retrieve its command line. For C programs built with Microsoft's
 * tools it is enough to make the program have a `wmain()` instead of
 * `main()`. `wmain()` has a wide character argument vector as parameter.
 *
 * At least currently, mingw doesn't support `wmain()`, so if you use
 * mingw to develop the spawned program, it should call
 * g_win32_get_command_line() to get arguments in UTF-8.
 *
 * On Windows the low-level child process creation API `CreateProcess()`
 * doesn't use argument vectors, but a command line. The C runtime
 * library's `spawn*()` family of functions (which g_spawn_async_with_pipes()
 * eventually calls) paste the argument vector elements together into
 * a command line, and the C runtime startup code does a corresponding
 * reconstruction of an argument vector from the command line, to be
 * passed to `main()`. Complications arise when you have argument vector
 * elements that contain spaces or double quotes. The `spawn*()` functions
 * don't do any quoting or escaping, but on the other hand the startup
 * code does do unquoting and unescaping in order to enable receiving
 * arguments with embedded spaces or double quotes. To work around this
 * asymmetry, g_spawn_async_with_pipes() will do quoting and escaping on
 * argument vector elements that need it before calling the C runtime
 * `spawn()` function.
 *
 * The returned @child_pid on Windows is a handle to the child
 * process, not its identifier. Process handles and process
 * identifiers are different concepts on Windows.
 *
 * @envp is a %NULL-terminated array of strings, where each string
 * has the form `KEY=VALUE`. This will become the child's environment.
 * If @envp is %NULL, the child inherits its parent's environment.
 *
 * @flags should be the bitwise OR of any flags you want to affect the
 * function's behaviour. The %G_SPAWN_DO_NOT_REAP_CHILD means that the
 * child will not automatically be reaped; you must use a child watch
 * (g_child_watch_add()) to be notified about the death of the child process,
 * otherwise it will stay around as a zombie process until this process exits.
 * Eventually you must call g_spawn_close_pid() on the @child_pid, in order to
 * free resources which may be associated with the child process. (On Unix,
 * using a child watch is equivalent to calling waitpid() or handling
 * the `SIGCHLD` signal manually. On Windows, calling g_spawn_close_pid()
 * is equivalent to calling `CloseHandle()` on the process handle returned
 * in @child_pid). See g_child_watch_add().
 *
 * Open UNIX file descriptors marked as `FD_CLOEXEC` will be automatically
 * closed in the child process. %G_SPAWN_LEAVE_DESCRIPTORS_OPEN means that
 * other open file descriptors will be inherited by the child; otherwise all
 * descriptors except stdin/stdout/stderr will be closed before calling `exec()`
 * in the child. %G_SPAWN_SEARCH_PATH means that @argv[0] need not be an
 * absolute path, it will be looked for in the `PATH` environment
 * variable. %G_SPAWN_SEARCH_PATH_FROM_ENVP means need not be an
 * absolute path, it will be looked for in the `PATH` variable from
 * @envp. If both %G_SPAWN_SEARCH_PATH and %G_SPAWN_SEARCH_PATH_FROM_ENVP
 * are used, the value from @envp takes precedence over the environment.
 *
 * %G_SPAWN_CHILD_INHERITS_STDIN means that the child will inherit the parent's
 * standard input (by default, the child's standard input is attached to
 * `/dev/null`). %G_SPAWN_STDIN_FROM_DEV_NULL explicitly imposes the default
 * behavior. Both flags cannot be enabled at the same time and, in both cases,
 * the @stdin_pipe_out argument is ignored.
 *
 * %G_SPAWN_STDOUT_TO_DEV_NULL means that the child's standard output
 * will be discarded (by default, it goes to the same location as the parent's
 * standard output). %G_SPAWN_CHILD_INHERITS_STDOUT explicitly imposes the
 * default behavior. Both flags cannot be enabled at the same time and, in
 * both cases, the @stdout_pipe_out argument is ignored.
 *
 * %G_SPAWN_STDERR_TO_DEV_NULL means that the child's standard error
 * will be discarded (by default, it goes to the same location as the parent's
 * standard error). %G_SPAWN_CHILD_INHERITS_STDERR explicitly imposes the
 * default behavior. Both flags cannot be enabled at the same time and, in
 * both cases, the @stderr_pipe_out argument is ignored.
 *
 * It is valid to pass the same FD in multiple parameters (e.g. you can pass
 * a single FD for both @stdout_fd and @stderr_fd, and include it in
 * @source_fds too).
 *
 * @source_fds and @target_fds allow zero or more FDs from this process to be
 * remapped to different FDs in the spawned process. If @n_fds is greater than
 * zero, @source_fds and @target_fds must both be non-%NULL and the same length.
 * Each FD in @source_fds is remapped to the FD number at the same index in
 * @target_fds. The source and target FD may be equal to simply propagate an FD
 * to the spawned process. FD remappings are processed after standard FDs, so
 * any target FDs which equal @stdin_fd, @stdout_fd or @stderr_fd will overwrite
 * them in the spawned process.
 *
 * @source_fds is supported on Windows since 2.72.
 *
 * %G_SPAWN_FILE_AND_ARGV_ZERO means that the first element of @argv is
 * the file to execute, while the remaining elements are the actual
 * argument vector to pass to the file. Normally g_spawn_async_with_pipes()
 * uses @argv[0] as the file to execute, and passes all of @argv to the child.
 *
 * @child_setup and @user_data are a function and user data. On POSIX
 * platforms, the function is called in the child after GLib has
 * performed all the setup it plans to perform (including creating
 * pipes, closing file descriptors, etc.) but before calling `exec()`.
 * That is, @child_setup is called just before calling `exec()` in the
 * child. Obviously actions taken in this function will only affect
 * the child, not the parent.
 *
 * On Windows, there is no separate `fork()` and `exec()` functionality.
 * Child processes are created and run with a single API call,
 * `CreateProcess()`. There is no sensible thing @child_setup
 * could be used for on Windows so it is ignored and not called.
 *
 * If non-%NULL, @child_pid will on Unix be filled with the child's
 * process ID. You can use the process ID to send signals to the child,
 * or to use g_child_watch_add() (or `waitpid()`) if you specified the
 * %G_SPAWN_DO_NOT_REAP_CHILD flag. On Windows, @child_pid will be
 * filled with a handle to the child process only if you specified the
 * %G_SPAWN_DO_NOT_REAP_CHILD flag. You can then access the child
 * process using the Win32 API, for example wait for its termination
 * with the `WaitFor*()` functions, or examine its exit code with
 * `GetExitCodeProcess()`. You should close the handle with `CloseHandle()`
 * or g_spawn_close_pid() when you no longer need it.
 *
 * If non-%NULL, the @stdin_pipe_out, @stdout_pipe_out, @stderr_pipe_out
 * locations will be filled with file descriptors for writing to the child's
 * standard input or reading from its standard output or standard error.
 * The caller of g_spawn_async_with_pipes() must close these file descriptors
 * when they are no longer in use. If these parameters are %NULL, the
 * corresponding pipe won't be created.
 *
 * If @stdin_pipe_out is %NULL, the child's standard input is attached to
 * `/dev/null` unless %G_SPAWN_CHILD_INHERITS_STDIN is set.
 *
 * If @stderr_pipe_out is NULL, the child's standard error goes to the same
 * location as the parent's standard error unless %G_SPAWN_STDERR_TO_DEV_NULL
 * is set.
 *
 * If @stdout_pipe_out is NULL, the child's standard output goes to the same
 * location as the parent's standard output unless %G_SPAWN_STDOUT_TO_DEV_NULL
 * is set.
 *
 * @error can be %NULL to ignore errors, or non-%NULL to report errors.
 * If an error is set, the function returns %FALSE. Errors are reported
 * even if they occur in the child (for example if the executable in
 * `@argv[0]` is not found). Typically the `message` field of returned
 * errors should be displayed to users. Possible errors are those from
 * the %G_SPAWN_ERROR domain.
 *
 * If an error occurs, @child_pid, @stdin_pipe_out, @stdout_pipe_out,
 * and @stderr_pipe_out will not be filled with valid values.
 *
 * If @child_pid is not %NULL and an error does not occur then the returned
 * process reference must be closed using g_spawn_close_pid().
 *
 * On modern UNIX platforms, GLib can use an efficient process launching
 * codepath driven internally by `posix_spawn()`. This has the advantage of
 * avoiding the fork-time performance costs of cloning the parent process
 * address space, and avoiding associated memory overcommit checks that are
 * not relevant in the context of immediately executing a distinct process.
 * This optimized codepath will be used provided that the following conditions
 * are met:
 *
 * 1. %G_SPAWN_DO_NOT_REAP_CHILD is set
 * 2. %G_SPAWN_LEAVE_DESCRIPTORS_OPEN is set
 * 3. %G_SPAWN_SEARCH_PATH_FROM_ENVP is not set
 * 4. @working_directory is %NULL
 * 5. @child_setup is %NULL
 * 6. The program is of a recognised binary format, or has a shebang.
 *    Otherwise, GLib will have to execute the program through the
 *    shell, which is not done using the optimized codepath.
 *
 * If you are writing a GTK application, and the program you are spawning is a
 * graphical application too, then to ensure that the spawned program opens its
 * windows on the right screen, you may want to use #GdkAppLaunchContext,
 * #GAppLaunchContext, or set the `DISPLAY` environment variable.
 *
 * Returns: %TRUE on success, %FALSE if an error was set
 *
 * Since: 2.68
 */
gboolean
g_spawn_async_with_pipes_and_fds (const gchar           *working_directory,
                                  const gchar * const   *argv,
                                  const gchar * const   *envp,
                                  GSpawnFlags            flags,
                                  GSpawnChildSetupFunc   child_setup,
                                  gpointer               user_data,
                                  gint                   stdin_fd,
                                  gint                   stdout_fd,
                                  gint                   stderr_fd,
                                  const gint            *source_fds,
                                  const gint            *target_fds,
                                  gsize                  n_fds,
                                  GPid                  *child_pid_out,
                                  gint                  *stdin_pipe_out,
                                  gint                  *stdout_pipe_out,
                                  gint                  *stderr_pipe_out,
                                  GError               **error)
{
  g_return_val_if_fail (argv != NULL, FALSE);
  g_return_val_if_fail (argv[0] != NULL, FALSE);
  /* can’t both inherit and set pipes to /dev/null */
  g_return_val_if_fail ((flags & INHERITS_OR_NULL_STDIN) != INHERITS_OR_NULL_STDIN, FALSE);
  g_return_val_if_fail ((flags & INHERITS_OR_NULL_STDOUT) != INHERITS_OR_NULL_STDOUT, FALSE);
  g_return_val_if_fail ((flags & INHERITS_OR_NULL_STDERR) != INHERITS_OR_NULL_STDERR, FALSE);
  /* can’t use pipes and stdin/stdout/stderr FDs */
  g_return_val_if_fail (stdin_pipe_out == NULL || stdin_fd < 0, FALSE);
  g_return_val_if_fail (stdout_pipe_out == NULL || stdout_fd < 0, FALSE);
  g_return_val_if_fail (stderr_pipe_out == NULL || stderr_fd < 0, FALSE);

  if ((flags & INHERITS_OR_NULL_STDIN) != 0)
    stdin_pipe_out = NULL;
  if ((flags & INHERITS_OR_NULL_STDOUT) != 0)
    stdout_pipe_out = NULL;
  if ((flags & INHERITS_OR_NULL_STDERR) != 0)
    stderr_pipe_out = NULL;

  return fork_exec (!(flags & G_SPAWN_DO_NOT_REAP_CHILD),
                    working_directory,
                    (const gchar * const *) argv,
                    (const gchar * const *) envp,
                    !(flags & G_SPAWN_LEAVE_DESCRIPTORS_OPEN),
                    (flags & G_SPAWN_SEARCH_PATH) != 0,
                    (flags & G_SPAWN_SEARCH_PATH_FROM_ENVP) != 0,
                    (flags & G_SPAWN_STDOUT_TO_DEV_NULL) != 0,
                    (flags & G_SPAWN_STDERR_TO_DEV_NULL) != 0,
                    (flags & G_SPAWN_CHILD_INHERITS_STDIN) != 0,
                    (flags & G_SPAWN_FILE_AND_ARGV_ZERO) != 0,
                    (flags & G_SPAWN_CLOEXEC_PIPES) != 0,
                    child_setup,
                    user_data,
                    child_pid_out,
                    stdin_pipe_out,
                    stdout_pipe_out,
                    stderr_pipe_out,
                    stdin_fd,
                    stdout_fd,
                    stderr_fd,
                    source_fds,
                    target_fds,
                    n_fds,
                    error);
}

/**
 * g_spawn_async_with_fds:
 * @working_directory: (type filename) (nullable): child's current working directory, or %NULL to inherit parent's, in the GLib file name encoding
 * @argv: (array zero-terminated=1): child's argument vector, in the GLib file name encoding;
 *   it must be non-empty and %NULL-terminated
 * @envp: (array zero-terminated=1) (nullable): child's environment, or %NULL to inherit parent's, in the GLib file name encoding
 * @flags: flags from #GSpawnFlags
 * @child_setup: (scope async) (closure user_data) (nullable): function to run
 *   in the child just before `exec()`
 * @user_data: user data for @child_setup
 * @child_pid: (out) (optional): return location for child process ID, or %NULL
 * @stdin_fd: file descriptor to use for child's stdin, or `-1`
 * @stdout_fd: file descriptor to use for child's stdout, or `-1`
 * @stderr_fd: file descriptor to use for child's stderr, or `-1`
 * @error: return location for error
 *
 * Executes a child program asynchronously.
 *
 * Identical to g_spawn_async_with_pipes_and_fds() but with `n_fds` set to zero,
 * so no FD assignments are used.
 *
 * Returns: %TRUE on success, %FALSE if an error was set
 *
 * Since: 2.58
 */
gboolean
g_spawn_async_with_fds (const gchar          *working_directory,
                        gchar               **argv,
                        gchar               **envp,
                        GSpawnFlags           flags,
                        GSpawnChildSetupFunc  child_setup,
                        gpointer              user_data,
                        GPid                 *child_pid,
                        gint                  stdin_fd,
                        gint                  stdout_fd,
                        gint                  stderr_fd,
                        GError              **error)
{
  g_return_val_if_fail (argv != NULL, FALSE);
  g_return_val_if_fail (argv[0] != NULL, FALSE);
  g_return_val_if_fail (stdout_fd < 0 ||
                        !(flags & G_SPAWN_STDOUT_TO_DEV_NULL), FALSE);
  g_return_val_if_fail (stderr_fd < 0 ||
                        !(flags & G_SPAWN_STDERR_TO_DEV_NULL), FALSE);
  /* can't inherit stdin if we have an input pipe. */
  g_return_val_if_fail (stdin_fd < 0 ||
                        !(flags & G_SPAWN_CHILD_INHERITS_STDIN), FALSE);

  return fork_exec (!(flags & G_SPAWN_DO_NOT_REAP_CHILD),
                    working_directory,
                    (const gchar * const *) argv,
                    (const gchar * const *) envp,
                    !(flags & G_SPAWN_LEAVE_DESCRIPTORS_OPEN),
                    (flags & G_SPAWN_SEARCH_PATH) != 0,
                    (flags & G_SPAWN_SEARCH_PATH_FROM_ENVP) != 0,
                    (flags & G_SPAWN_STDOUT_TO_DEV_NULL) != 0,
                    (flags & G_SPAWN_STDERR_TO_DEV_NULL) != 0,
                    (flags & G_SPAWN_CHILD_INHERITS_STDIN) != 0,
                    (flags & G_SPAWN_FILE_AND_ARGV_ZERO) != 0,
                    (flags & G_SPAWN_CLOEXEC_PIPES) != 0,
                    child_setup,
                    user_data,
                    child_pid,
                    NULL, NULL, NULL,
                    stdin_fd,
                    stdout_fd,
                    stderr_fd,
                    NULL, NULL, 0,
                    error);
}

/**
 * g_spawn_command_line_sync:
 * @command_line: (type filename): a command line
 * @standard_output: (out) (array zero-terminated=1) (element-type guint8) (optional): return location for child output
 * @standard_error: (out) (array zero-terminated=1) (element-type guint8) (optional): return location for child errors
 * @wait_status: (out) (optional): return location for child wait status, as returned by waitpid()
 * @error: return location for errors
 *
 * A simple version of g_spawn_sync() with little-used parameters
 * removed, taking a command line instead of an argument vector.
 *
 * See g_spawn_sync() for full details.
 *
 * The @command_line argument will be parsed by g_shell_parse_argv().
 *
 * Unlike g_spawn_sync(), the %G_SPAWN_SEARCH_PATH flag is enabled.
 * Note that %G_SPAWN_SEARCH_PATH can have security implications, so
 * consider using g_spawn_sync() directly if appropriate.
 *
 * Possible errors are those from g_spawn_sync() and those
 * from g_shell_parse_argv().
 *
 * If @wait_status is non-%NULL, the platform-specific status of
 * the child is stored there; see the documentation of
 * g_spawn_check_wait_status() for how to use and interpret this.
 * On Unix platforms, note that it is usually not equal
 * to the integer passed to `exit()` or returned from `main()`.
 * 
 * On Windows, please note the implications of g_shell_parse_argv()
 * parsing @command_line. Parsing is done according to Unix shell rules, not 
 * Windows command interpreter rules.
 * Space is a separator, and backslashes are
 * special. Thus you cannot simply pass a @command_line containing
 * canonical Windows paths, like "c:\\program files\\app\\app.exe", as
 * the backslashes will be eaten, and the space will act as a
 * separator. You need to enclose such paths with single quotes, like
 * "'c:\\program files\\app\\app.exe' 'e:\\folder\\argument.txt'".
 *
 * Returns: %TRUE on success, %FALSE if an error was set
 **/
gboolean
g_spawn_command_line_sync (const gchar  *command_line,
                           gchar       **standard_output,
                           gchar       **standard_error,
                           gint         *wait_status,
                           GError      **error)
{
  gboolean retval;
  gchar **argv = NULL;

  g_return_val_if_fail (command_line != NULL, FALSE);
  
  /* This will return a runtime error if @command_line is the empty string. */
  if (!g_shell_parse_argv (command_line,
                           NULL, &argv,
                           error))
    return FALSE;
  
  retval = g_spawn_sync (NULL,
                         argv,
                         NULL,
                         G_SPAWN_SEARCH_PATH,
                         NULL,
                         NULL,
                         standard_output,
                         standard_error,
                         wait_status,
                         error);
  g_strfreev (argv);

  return retval;
}

/**
 * g_spawn_command_line_async:
 * @command_line: (type filename): a command line
 * @error: return location for errors
 * 
 * A simple version of g_spawn_async() that parses a command line with
 * g_shell_parse_argv() and passes it to g_spawn_async().
 *
 * Runs a command line in the background. Unlike g_spawn_async(), the
 * %G_SPAWN_SEARCH_PATH flag is enabled, other flags are not. Note
 * that %G_SPAWN_SEARCH_PATH can have security implications, so
 * consider using g_spawn_async() directly if appropriate. Possible
 * errors are those from g_shell_parse_argv() and g_spawn_async().
 * 
 * The same concerns on Windows apply as for g_spawn_command_line_sync().
 *
 * Returns: %TRUE on success, %FALSE if error is set
 **/
gboolean
g_spawn_command_line_async (const gchar *command_line,
                            GError     **error)
{
  gboolean retval;
  gchar **argv = NULL;

  g_return_val_if_fail (command_line != NULL, FALSE);

  /* This will return a runtime error if @command_line is the empty string. */
  if (!g_shell_parse_argv (command_line,
                           NULL, &argv,
                           error))
    return FALSE;
  
  retval = g_spawn_async (NULL,
                          argv,
                          NULL,
                          G_SPAWN_SEARCH_PATH,
                          NULL,
                          NULL,
                          NULL,
                          error);
  g_strfreev (argv);

  return retval;
}

/**
 * g_spawn_check_wait_status:
 * @wait_status: A platform-specific wait status as returned from g_spawn_sync()
 * @error: a #GError
 *
 * Set @error if @wait_status indicates the child exited abnormally
 * (e.g. with a nonzero exit code, or via a fatal signal).
 *
 * The g_spawn_sync() and g_child_watch_add() family of APIs return the
 * status of subprocesses encoded in a platform-specific way.
 * On Unix, this is guaranteed to be in the same format waitpid() returns,
 * and on Windows it is guaranteed to be the result of GetExitCodeProcess().
 *
 * Prior to the introduction of this function in GLib 2.34, interpreting
 * @wait_status required use of platform-specific APIs, which is problematic
 * for software using GLib as a cross-platform layer.
 *
 * Additionally, many programs simply want to determine whether or not
 * the child exited successfully, and either propagate a #GError or
 * print a message to standard error. In that common case, this function
 * can be used. Note that the error message in @error will contain
 * human-readable information about the wait status.
 *
 * The @domain and @code of @error have special semantics in the case
 * where the process has an "exit code", as opposed to being killed by
 * a signal. On Unix, this happens if WIFEXITED() would be true of
 * @wait_status. On Windows, it is always the case.
 *
 * The special semantics are that the actual exit code will be the
 * code set in @error, and the domain will be %G_SPAWN_EXIT_ERROR.
 * This allows you to differentiate between different exit codes.
 *
 * If the process was terminated by some means other than an exit
 * status (for example if it was killed by a signal), the domain will be
 * %G_SPAWN_ERROR and the code will be %G_SPAWN_ERROR_FAILED.
 *
 * This function just offers convenience; you can of course also check
 * the available platform via a macro such as %G_OS_UNIX, and use
 * WIFEXITED() and WEXITSTATUS() on @wait_status directly. Do not attempt
 * to scan or parse the error message string; it may be translated and/or
 * change in future versions of GLib.
 *
 * Prior to version 2.70, g_spawn_check_exit_status() provides the same
 * functionality, although under a misleading name.
 *
 * Returns: %TRUE if child exited successfully, %FALSE otherwise (and
 *   @error will be set)
 *
 * Since: 2.70
 */
gboolean
g_spawn_check_wait_status (gint      wait_status,
			   GError  **error)
{
  gboolean ret = FALSE;

  if (WIFEXITED (wait_status))
    {
      if (WEXITSTATUS (wait_status) != 0)
	{
	  g_set_error (error, G_SPAWN_EXIT_ERROR, WEXITSTATUS (wait_status),
		       _("Child process exited with code %ld"),
		       (long) WEXITSTATUS (wait_status));
	  goto out;
	}
    }
  else if (WIFSIGNALED (wait_status))
    {
      g_set_error (error, G_SPAWN_ERROR, G_SPAWN_ERROR_FAILED,
		   _("Child process killed by signal %ld"),
		   (long) WTERMSIG (wait_status));
      goto out;
    }
  else if (WIFSTOPPED (wait_status))
    {
      g_set_error (error, G_SPAWN_ERROR, G_SPAWN_ERROR_FAILED,
		   _("Child process stopped by signal %ld"),
		   (long) WSTOPSIG (wait_status));
      goto out;
    }
  else
    {
      g_set_error (error, G_SPAWN_ERROR, G_SPAWN_ERROR_FAILED,
		   _("Child process exited abnormally"));
      goto out;
    }

  ret = TRUE;
 out:
  return ret;
}

/**
 * g_spawn_check_exit_status:
 * @wait_status: A status as returned from g_spawn_sync()
 * @error: a #GError
 *
 * An old name for g_spawn_check_wait_status(), deprecated because its
 * name is misleading.
 *
 * Despite the name of the function, @wait_status must be the wait status
 * as returned by g_spawn_sync(), g_subprocess_get_status(), `waitpid()`,
 * etc. On Unix platforms, it is incorrect for it to be the exit status
 * as passed to `exit()` or returned by g_subprocess_get_exit_status() or
 * `WEXITSTATUS()`.
 *
 * Returns: %TRUE if child exited successfully, %FALSE otherwise (and
 *     @error will be set)
 *
 * Since: 2.34
 *
 * Deprecated: 2.70: Use g_spawn_check_wait_status() instead, and check whether your code is conflating wait and exit statuses.
 */
gboolean
g_spawn_check_exit_status (gint      wait_status,
                           GError  **error)
{
  return g_spawn_check_wait_status (wait_status, error);
}

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)). */
static gssize
write_all (gint fd, gconstpointer vbuf, gsize to_write)
{
  gchar *buf = (gchar *) vbuf;
  
  while (to_write > 0)
    {
      gssize count = write (fd, buf, to_write);
      if (count < 0)
        {
          if (errno != EINTR)
            return FALSE;
        }
      else
        {
          to_write -= count;
          buf += count;
        }
    }
  
  return TRUE;
}

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)). */
G_NORETURN
static void
write_err_and_exit (gint fd, gint msg)
{
  gint en = errno;
  
  write_all (fd, &msg, sizeof(msg));
  write_all (fd, &en, sizeof(en));
  
  _exit (1);
}

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)). */
static int
set_cloexec (void *data, gint fd)
{
  if (fd >= GPOINTER_TO_INT (data))
    fcntl (fd, F_SETFD, FD_CLOEXEC);

  return 0;
}

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)). */
static void
unset_cloexec (int fd)
{
  int flags;
  int result;

  flags = fcntl (fd, F_GETFD, 0);

  if (flags != -1)
    {
      int errsv;
      flags &= (~FD_CLOEXEC);
      do
        {
          result = fcntl (fd, F_SETFD, flags);
          errsv = errno;
        }
      while (result == -1 && errsv == EINTR);
    }
}

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)). */
static int
dupfd_cloexec (int old_fd, int new_fd_min)
{
  int fd, errsv;
#ifdef F_DUPFD_CLOEXEC
  do
    {
      fd = fcntl (old_fd, F_DUPFD_CLOEXEC, new_fd_min);
      errsv = errno;
    }
  while (fd == -1 && errsv == EINTR);
#else
  /* OS X Snow Lion and earlier don't have F_DUPFD_CLOEXEC:
   * https://bugzilla.gnome.org/show_bug.cgi?id=710962
   */
  int result, flags;
  do
    {
      fd = fcntl (old_fd, F_DUPFD, new_fd_min);
      errsv = errno;
    }
  while (fd == -1 && errsv == EINTR);
  flags = fcntl (fd, F_GETFD, 0);
  if (flags != -1)
    {
      flags |= FD_CLOEXEC;
      do
        {
          result = fcntl (fd, F_SETFD, flags);
          errsv = errno;
        }
      while (result == -1 && errsv == EINTR);
    }
#endif
  return fd;
}

/* fdwalk()-compatible callback to close a fd for non-compliant
 * implementations of fdwalk() that potentially pass already
 * closed fds.
 *
 * It is not an error to pass an invalid fd to this function.
 *
 * This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)).
 */
G_GNUC_UNUSED static int
close_func_with_invalid_fds (void *data, int fd)
{
  /* We use close and not g_close here because on some platforms, we
   * don't know how to close only valid, open file descriptors, so we
   * have to pass bad fds to close too. g_close warns if given a bad
   * fd.
   *
   * This function returns no error, because there is nothing that the caller
   * could do with that information. That is even the case for EINTR. See
   * g_close() about the specialty of EINTR and why that is correct.
   * If g_close() ever gets extended to handle EINTR specially, then this place
   * should get updated to do the same handling.
   */
  if (fd >= GPOINTER_TO_INT (data))
    close (fd);

  return 0;
}

#ifdef __linux__
struct linux_dirent64
{
  guint64        d_ino;    /* 64-bit inode number */
  guint64        d_off;    /* 64-bit offset to next structure */
  unsigned short d_reclen; /* Size of this dirent */
  unsigned char  d_type;   /* File type */
  char           d_name[]; /* Filename (null-terminated) */
};

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)). */
static gint
filename_to_fd (const char *p)
{
  char c;
  int fd = 0;
  const int cutoff = G_MAXINT / 10;
  const int cutlim = G_MAXINT % 10;

  if (*p == '\0')
    return -1;

  while ((c = *p++) != '\0')
    {
      if (c < '0' || c > '9')
        return -1;
      c -= '0';

      /* Check for overflow. */
      if (fd > cutoff || (fd == cutoff && c > cutlim))
        return -1;

      fd = fd * 10 + c;
    }

  return fd;
}
#endif

static int safe_fdwalk_with_invalid_fds (int (*cb)(void *data, int fd), void *data);

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)). */
static int
safe_fdwalk (int (*cb)(void *data, int fd), void *data)
{
#if 0
  /* Use fdwalk function provided by the system if it is known to be
   * async-signal safe.
   *
   * Currently there are no operating systems known to provide a safe
   * implementation, so this section is not used for now.
   */
  return fdwalk (cb, data);
#else
  /* Fallback implementation of fdwalk. It should be async-signal safe, but it
   * may fail on non-Linux operating systems. See safe_fdwalk_with_invalid_fds
   * for a slower alternative.
   */

#ifdef __linux__
  gint fd;
  gint res = 0;

  /* Avoid use of opendir/closedir since these are not async-signal-safe. */
  int dir_fd = open ("/proc/self/fd", O_RDONLY | O_DIRECTORY);
  if (dir_fd >= 0)
    {
      /* buf needs to be aligned correctly to receive linux_dirent64.
       * C11 has _Alignof for this purpose, but for now a
       * union serves the same purpose. */
      union
      {
        char buf[4096];
        struct linux_dirent64 alignment;
      } u;
      int pos, nread;
      struct linux_dirent64 *de;

      while ((nread = syscall (SYS_getdents64, dir_fd, u.buf, sizeof (u.buf))) > 0)
        {
          for (pos = 0; pos < nread; pos += de->d_reclen)
            {
              de = (struct linux_dirent64 *) (u.buf + pos);

              fd = filename_to_fd (de->d_name);
              if (fd < 0 || fd == dir_fd)
                  continue;

              if ((res = cb (data, fd)) != 0)
                  break;
            }
        }

      g_close (dir_fd, NULL);
      return res;
    }

  /* If /proc is not mounted or not accessible we fail here and rely on
   * safe_fdwalk_with_invalid_fds to fall back to the old
   * rlimit trick. */

#endif

#if defined(__sun__) && defined(F_PREVFD) && defined(F_NEXTFD)
/*
 * Solaris 11.4 has a signal-safe way which allows
 * us to find all file descriptors in a process.
 *
 * fcntl(fd, F_NEXTFD, maxfd)
 * - returns the first allocated file descriptor <= maxfd  > fd.
 *
 * fcntl(fd, F_PREVFD)
 * - return highest allocated file descriptor < fd.
 */
  gint fd;
  gint res = 0;

  open_max = fcntl (INT_MAX, F_PREVFD); /* find the maximum fd */
  if (open_max < 0) /* No open files */
    return 0;

  for (fd = -1; (fd = fcntl (fd, F_NEXTFD, open_max)) != -1; )
    if ((res = cb (data, fd)) != 0 || fd == open_max)
      break;

  return res;
#endif

  return safe_fdwalk_with_invalid_fds (cb, data);
#endif
}

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)). */
static int
safe_fdwalk_with_invalid_fds (int (*cb)(void *data, int fd), void *data)
{
  /* Fallback implementation of fdwalk. It should be async-signal safe, but it
   * may be slow, especially on systems allowing very high number of open file
   * descriptors.
   */
  gint open_max = -1;
  gint fd;
  gint res = 0;

#if 0 && defined(HAVE_SYS_RESOURCE_H)
  struct rlimit rl;

  /* Use getrlimit() function provided by the system if it is known to be
   * async-signal safe.
   *
   * Currently there are no operating systems known to provide a safe
   * implementation, so this section is not used for now.
   */
  if (getrlimit (RLIMIT_NOFILE, &rl) == 0 && rl.rlim_max != RLIM_INFINITY)
    open_max = rl.rlim_max;
#endif
#if defined(__FreeBSD__) || defined(__OpenBSD__) || defined(__APPLE__)
  /* Use sysconf() function provided by the system if it is known to be
   * async-signal safe.
   *
   * FreeBSD: sysconf() is included in the list of async-signal safe functions
   * found in https://man.freebsd.org/sigaction(2).
   *
   * OpenBSD: sysconf() is included in the list of async-signal safe functions
   * found in https://man.openbsd.org/sigaction.2.
   * 
   * Apple: sysconf() is included in the list of async-signal safe functions
   * found in https://opensource.apple.com/source/xnu/xnu-517.12.7/bsd/man/man2/sigaction.2
   */
  if (open_max < 0)
    open_max = sysconf (_SC_OPEN_MAX);
#endif
  /* Hardcoded fallback: the default process hard limit in Linux as of 2020 */
  if (open_max < 0)
    open_max = 4096;

#if defined(__APPLE__)
  /* proc_pidinfo isn't documented as async-signal-safe but looking at the implementation
   * in the darwin tree here:
   *
   * https://opensource.apple.com/source/Libc/Libc-498/darwin/libproc.c.auto.html
   *
   * It's just a thin wrapper around a syscall, so it's probably okay.
   */
  {
    char buffer[4096 * PROC_PIDLISTFD_SIZE];
    ssize_t buffer_size;

    buffer_size = proc_pidinfo (getpid (), PROC_PIDLISTFDS, 0, buffer, sizeof (buffer));

    if (buffer_size > 0 &&
        sizeof (buffer) >= (size_t) buffer_size &&
        (buffer_size % PROC_PIDLISTFD_SIZE) == 0)
      {
        const struct proc_fdinfo *fd_info = (const struct proc_fdinfo *) buffer;
        size_t number_of_fds = (size_t) buffer_size / PROC_PIDLISTFD_SIZE;

        for (size_t i = 0; i < number_of_fds; i++)
          if ((res = cb (data, fd_info[i].proc_fd)) != 0)
            break;

        return res;
      }
  }
#endif

  for (fd = 0; fd < open_max; fd++)
      if ((res = cb (data, fd)) != 0)
          break;

  return res;
}

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)). */
static int
safe_fdwalk_set_cloexec (int lowfd)
{
  int ret;

#if defined(HAVE_CLOSE_RANGE) && defined(CLOSE_RANGE_CLOEXEC)
  /* close_range() is available in Linux since kernel 5.9, and on FreeBSD at
   * around the same time. It was designed for use in async-signal-safe
   * situations: https://bugs.python.org/issue38061
   *
   * The `CLOSE_RANGE_CLOEXEC` flag was added in Linux 5.11, and is not yet
   * present in FreeBSD.
   *
   * Handle ENOSYS in case it’s supported in libc but not the kernel; if so,
   * fall back to safe_fdwalk(). Handle EINVAL in case `CLOSE_RANGE_CLOEXEC`
   * is not supported. */
  ret = close_range (lowfd, G_MAXUINT, CLOSE_RANGE_CLOEXEC);
  if (ret == 0 || !(errno == ENOSYS || errno == EINVAL))
    return ret;
#endif  /* HAVE_CLOSE_RANGE */

  ret = safe_fdwalk (set_cloexec, GINT_TO_POINTER (lowfd));

  return ret;
}

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)).
 *
 * On failure, `-1` will be returned and errno will be set. */
static int
safe_closefrom (int lowfd)
{
  int ret;

#if defined(HAVE_CLOSE_RANGE)
  /* close_range() is available in Linux since kernel 5.9, and on FreeBSD at
   * around the same time. It was designed for use in async-signal-safe
   * situations: https://bugs.python.org/issue38061
   *
   * Handle ENOSYS in case it’s supported in libc but not the kernel; if so,
   * fall back to safe_fdwalk(). */
  ret = close_range (lowfd, G_MAXUINT, 0);
  if (ret == 0 || errno != ENOSYS)
    return ret;
#endif  /* HAVE_CLOSE_RANGE */

#if defined(__FreeBSD__) || defined(__OpenBSD__) || \
  (defined(__sun__) && defined(F_CLOSEFROM))
  /* Use closefrom function provided by the system if it is known to be
   * async-signal safe.
   *
   * FreeBSD: closefrom is included in the list of async-signal safe functions
   * found in https://man.freebsd.org/sigaction(2).
   *
   * OpenBSD: closefrom is not included in the list, but a direct system call
   * should be safe to use.
   *
   * In Solaris as of 11.3 SRU 31, closefrom() is also a direct system call.
   * On such systems, F_CLOSEFROM is defined.
   */
  (void) closefrom (lowfd);
  return 0;
#elif defined(__DragonFly__)
  /* It is unclear whether closefrom function included in DragonFlyBSD libc_r
   * is safe to use because it calls a lot of library functions. It is also
   * unclear whether libc_r itself is still being used. Therefore, we do a
   * direct system call here ourselves to avoid possible issues.
   */
  (void) syscall (SYS_closefrom, lowfd);
  return 0;
#elif defined(F_CLOSEM)
  /* NetBSD and AIX have a special fcntl command which does the same thing as
   * closefrom. NetBSD also includes closefrom function, which seems to be a
   * simple wrapper of the fcntl command.
   */
  return fcntl (lowfd, F_CLOSEM);
#else
  ret = safe_fdwalk (close_func_with_invalid_fds, GINT_TO_POINTER (lowfd));

  return ret;
#endif
}

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)). */
static gint
safe_dup2 (gint fd1, gint fd2)
{
  gint ret;

  do
    ret = dup2 (fd1, fd2);
  while (ret < 0 && (errno == EINTR || errno == EBUSY));

  return ret;
}

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)). */
static gboolean
relocate_fd_out_of_standard_range (gint *fd)
{
  gint ret = -1;
  const int min_fileno = STDERR_FILENO + 1;

  do
    ret = fcntl (*fd, F_DUPFD, min_fileno);
  while (ret < 0 && errno == EINTR);

  /* Note we don't need to close the old fd, because the caller is expected
   * to close fds in the standard range itself.
   */
  if (ret >= min_fileno)
    {
      *fd = ret;
      return TRUE;
    }

  return FALSE;
}

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)). */
static gint
safe_open (const char *path, gint mode)
{
  gint ret;

  do
    ret = open (path, mode);
  while (ret < 0 && errno == EINTR);

  return ret;
}

enum
{
  CHILD_CHDIR_FAILED,
  CHILD_EXEC_FAILED,
  CHILD_OPEN_FAILED,
  CHILD_DUPFD_FAILED,
  CHILD_FORK_FAILED,
  CHILD_CLOSE_FAILED,
};

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)) until it calls exec().
 *
 * All callers must guarantee that @argv and @argv[0] are non-NULL. */
static void
do_exec (gint                  child_err_report_fd,
         gint                  stdin_fd,
         gint                  stdout_fd,
         gint                  stderr_fd,
         gint                 *source_fds,
         const gint           *target_fds,
         gsize                 n_fds,
         const gchar          *working_directory,
         const gchar * const  *argv,
         gchar               **argv_buffer,
         gsize                 argv_buffer_len,
         const gchar * const  *envp,
         gboolean              close_descriptors,
         const gchar          *search_path,
         gchar                *search_path_buffer,
         gsize                 search_path_buffer_len,
         gboolean              stdout_to_null,
         gboolean              stderr_to_null,
         gboolean              child_inherits_stdin,
         gboolean              file_and_argv_zero,
         GSpawnChildSetupFunc  child_setup,
         gpointer              user_data)
{
  gsize i;
  gint max_target_fd = 0;

  if (working_directory && chdir (working_directory) < 0)
    write_err_and_exit (child_err_report_fd,
                        CHILD_CHDIR_FAILED);

  /* It's possible the caller assigned stdin to an fd with a
   * file number that is supposed to be reserved for
   * stdout or stderr.
   *
   * If so, move it up out of the standard range, so it doesn't
   * cause a conflict.
   */
  if (IS_STD_FILENO (stdin_fd) && stdin_fd != STDIN_FILENO)
    {
      int old_fd = stdin_fd;

      if (!relocate_fd_out_of_standard_range (&stdin_fd))
        write_err_and_exit (child_err_report_fd, CHILD_DUPFD_FAILED);

      if (stdout_fd == old_fd)
        stdout_fd = stdin_fd;

      if (stderr_fd == old_fd)
        stderr_fd = stdin_fd;
    }

  /* Redirect pipes as required
   *
   * There are two cases where we don't need to do the redirection
   * 1. Where the associated file descriptor is cleared/invalid
   * 2. When the associated file descriptor is already given the
   * correct file number.
   */
  if (IS_VALID_FILENO (stdin_fd) && stdin_fd != STDIN_FILENO)
    {
      if (safe_dup2 (stdin_fd, 0) < 0)
        write_err_and_exit (child_err_report_fd,
                            CHILD_DUPFD_FAILED);

      set_cloexec (GINT_TO_POINTER(0), stdin_fd);
    }
  else if (!child_inherits_stdin)
    {
      /* Keep process from blocking on a read of stdin */
      gint read_null = safe_open ("/dev/null", O_RDONLY);
      if (read_null < 0)
        write_err_and_exit (child_err_report_fd,
                            CHILD_OPEN_FAILED);
      if (safe_dup2 (read_null, 0) < 0)
        write_err_and_exit (child_err_report_fd,
                            CHILD_DUPFD_FAILED);
      close_and_invalidate (&read_null);
    }

  /* Like with stdin above, it's possible the caller assigned
   * stdout to an fd with a file number that's intruding on the
   * standard range.
   *
   * If so, move it out of the way, too.
   */
  if (IS_STD_FILENO (stdout_fd) && stdout_fd != STDOUT_FILENO)
    {
      int old_fd = stdout_fd;

      if (!relocate_fd_out_of_standard_range (&stdout_fd))
        write_err_and_exit (child_err_report_fd, CHILD_DUPFD_FAILED);

      if (stderr_fd == old_fd)
        stderr_fd = stdout_fd;
    }

  if (IS_VALID_FILENO (stdout_fd) && stdout_fd != STDOUT_FILENO)
    {
      if (safe_dup2 (stdout_fd, 1) < 0)
        write_err_and_exit (child_err_report_fd,
                            CHILD_DUPFD_FAILED);

      set_cloexec (GINT_TO_POINTER(0), stdout_fd);
    }
  else if (stdout_to_null)
    {
      gint write_null = safe_open ("/dev/null", O_WRONLY);
      if (write_null < 0)
        write_err_and_exit (child_err_report_fd,
                            CHILD_OPEN_FAILED);
      if (safe_dup2 (write_null, 1) < 0)
        write_err_and_exit (child_err_report_fd,
                            CHILD_DUPFD_FAILED);
      close_and_invalidate (&write_null);
    }

  if (IS_STD_FILENO (stderr_fd) && stderr_fd != STDERR_FILENO)
    {
      if (!relocate_fd_out_of_standard_range (&stderr_fd))
        write_err_and_exit (child_err_report_fd, CHILD_DUPFD_FAILED);
    }

  /* Like with stdin/stdout above, it's possible the caller assigned
   * stderr to an fd with a file number that's intruding on the
   * standard range.
   *
   * Make sure it's out of the way, also.
   */
  if (IS_VALID_FILENO (stderr_fd) && stderr_fd != STDERR_FILENO)
    {
      if (safe_dup2 (stderr_fd, 2) < 0)
        write_err_and_exit (child_err_report_fd,
                            CHILD_DUPFD_FAILED);

      set_cloexec (GINT_TO_POINTER(0), stderr_fd);
    }
  else if (stderr_to_null)
    {
      gint write_null = safe_open ("/dev/null", O_WRONLY);
      if (write_null < 0)
        write_err_and_exit (child_err_report_fd,
                            CHILD_OPEN_FAILED);
      if (safe_dup2 (write_null, 2) < 0)
        write_err_and_exit (child_err_report_fd,
                            CHILD_DUPFD_FAILED);
      close_and_invalidate (&write_null);
    }

  /* Close all file descriptors but stdin, stdout and stderr, and any of source_fds,
   * before we exec. Note that this includes
   * child_err_report_fd, which keeps the parent from blocking
   * forever on the other end of that pipe.
   */
  if (close_descriptors)
    {
      if (child_setup == NULL && n_fds == 0)
        {
          if (safe_dup2 (child_err_report_fd, 3) < 0)
            write_err_and_exit (child_err_report_fd, CHILD_DUPFD_FAILED);
          set_cloexec (GINT_TO_POINTER (0), 3);
          if (safe_closefrom (4) < 0)
            write_err_and_exit (child_err_report_fd, CHILD_CLOSE_FAILED);
          child_err_report_fd = 3;
        }
      else
        {
          if (safe_fdwalk_set_cloexec (3) < 0)
            write_err_and_exit (child_err_report_fd, CHILD_CLOSE_FAILED);
        }
    }
  else
    {
      /* We need to do child_err_report_fd anyway */
      set_cloexec (GINT_TO_POINTER (0), child_err_report_fd);
    }

  /*
   * Work through the @source_fds and @target_fds mapping.
   *
   * Based on code originally derived from
   * gnome-terminal:src/terminal-screen.c:terminal_screen_child_setup(),
   * used under the LGPLv2+ with permission from author. (The code has
   * since migrated to vte:src/spawn.cc:SpawnContext::exec and is no longer
   * terribly similar to what we have here.)
   */

  if (n_fds > 0)
    {
      for (i = 0; i < n_fds; i++)
        max_target_fd = MAX (max_target_fd, target_fds[i]);

      if (max_target_fd == G_MAXINT)
        {
          errno = EINVAL;
          write_err_and_exit (child_err_report_fd, CHILD_DUPFD_FAILED);
        }

      /* If we're doing remapping fd assignments, we need to handle
       * the case where the user has specified e.g. 5 -> 4, 4 -> 6.
       * We do this by duping all source fds, taking care to ensure the new
       * fds are larger than any target fd to avoid introducing new conflicts.
       */
      for (i = 0; i < n_fds; i++)
        {
          if (source_fds[i] != target_fds[i])
            {
              source_fds[i] = dupfd_cloexec (source_fds[i], max_target_fd + 1);
              if (source_fds[i] < 0)
                write_err_and_exit (child_err_report_fd, CHILD_DUPFD_FAILED);
            }
        }

      for (i = 0; i < n_fds; i++)
        {
          /* For basic fd assignments (where source == target), we can just
           * unset FD_CLOEXEC.
           */
          if (source_fds[i] == target_fds[i])
            {
              unset_cloexec (source_fds[i]);
            }
          else
            {
              /* If any of the @target_fds conflict with @child_err_report_fd,
               * dup it so it doesn’t get conflated.
               */
              if (target_fds[i] == child_err_report_fd)
                {
                  child_err_report_fd = dupfd_cloexec (child_err_report_fd, max_target_fd + 1);
                  if (child_err_report_fd < 0)
                    write_err_and_exit (child_err_report_fd, CHILD_DUPFD_FAILED);
                }

              if (safe_dup2 (source_fds[i], target_fds[i]) < 0)
                write_err_and_exit (child_err_report_fd, CHILD_DUPFD_FAILED);

              close_and_invalidate (&source_fds[i]);
            }
        }
    }

  /* Call user function just before we exec */
  if (child_setup)
    {
      (* child_setup) (user_data);
    }

  g_execute (argv[0],
             (gchar **) (file_and_argv_zero ? argv + 1 : argv),
             argv_buffer, argv_buffer_len,
             (gchar **) envp, search_path, search_path_buffer, search_path_buffer_len);

  /* Exec failed */
  write_err_and_exit (child_err_report_fd,
                      CHILD_EXEC_FAILED);
}

static gboolean
read_ints (int      fd,
           gint*    buf,
           gint     n_ints_in_buf,    
           gint    *n_ints_read,      
           GError **error)
{
  gsize bytes = 0;    
  
  while (TRUE)
    {
      gssize chunk;    

      if (bytes >= sizeof(gint)*2)
        break; /* give up, who knows what happened, should not be
                * possible.
                */
          
    again:
      chunk = read (fd,
                    ((gchar*)buf) + bytes,
                    sizeof(gint) * n_ints_in_buf - bytes);
      if (chunk < 0 && errno == EINTR)
        goto again;
          
      if (chunk < 0)
        {
          int errsv = errno;

          /* Some weird shit happened, bail out */
          g_set_error (error,
                       G_SPAWN_ERROR,
                       G_SPAWN_ERROR_FAILED,
                       _("Failed to read from child pipe (%s)"),
                       g_strerror (errsv));

          return FALSE;
        }
      else if (chunk == 0)
        break; /* EOF */
      else /* chunk > 0 */
	bytes += chunk;
    }

  *n_ints_read = (gint)(bytes / sizeof(gint));

  return TRUE;
}

#ifdef POSIX_SPAWN_AVAILABLE
static gboolean
do_posix_spawn (const gchar * const *argv,
                const gchar * const *envp,
                gboolean    search_path,
                gboolean    stdout_to_null,
                gboolean    stderr_to_null,
                gboolean    child_inherits_stdin,
                gboolean    file_and_argv_zero,
                GPid       *child_pid,
                gint       *child_close_fds,
                gint        stdin_fd,
                gint        stdout_fd,
                gint        stderr_fd,
                const gint *source_fds,
                const gint *target_fds,
                gsize       n_fds)
{
  pid_t pid;
  gint *duped_source_fds = NULL;
  gint max_target_fd = 0;
  const gchar * const *argv_pass;
  posix_spawnattr_t attr;
  posix_spawn_file_actions_t file_actions;
  gint parent_close_fds[3];
  gsize num_parent_close_fds = 0;
  GSList *child_close = NULL;
  GSList *elem;
  sigset_t mask;
  gsize i;
  int r;

  g_assert (argv != NULL && argv[0] != NULL);

  if (*argv[0] == '\0')
    {
      /* We check the simple case first. */
      return ENOENT;
    }

  r = posix_spawnattr_init (&attr);
  if (r != 0)
    return r;

  if (child_close_fds)
    {
      int i = -1;
      while (child_close_fds[++i] != -1)
        child_close = g_slist_prepend (child_close,
                                       GINT_TO_POINTER (child_close_fds[i]));
    }

  r = posix_spawnattr_setflags (&attr, POSIX_SPAWN_SETSIGDEF);
  if (r != 0)
    goto out_free_spawnattr;

  /* Reset some signal handlers that we may use */
  sigemptyset (&mask);
  sigaddset (&mask, SIGCHLD);
  sigaddset (&mask, SIGINT);
  sigaddset (&mask, SIGTERM);
  sigaddset (&mask, SIGHUP);

  r = posix_spawnattr_setsigdefault (&attr, &mask);
  if (r != 0)
    goto out_free_spawnattr;

  r = posix_spawn_file_actions_init (&file_actions);
  if (r != 0)
    goto out_free_spawnattr;

  /* Redirect pipes as required */

  if (stdin_fd >= 0)
    {
      r = posix_spawn_file_actions_adddup2 (&file_actions, stdin_fd, 0);
      if (r != 0)
        goto out_close_fds;

      if (!g_slist_find (child_close, GINT_TO_POINTER (stdin_fd)))
        child_close = g_slist_prepend (child_close, GINT_TO_POINTER (stdin_fd));
    }
  else if (!child_inherits_stdin)
    {
      /* Keep process from blocking on a read of stdin */
      gint read_null = safe_open ("/dev/null", O_RDONLY | O_CLOEXEC);
      g_assert (read_null != -1);
      parent_close_fds[num_parent_close_fds++] = read_null;

#ifndef HAVE_O_CLOEXEC
      fcntl (read_null, F_SETFD, FD_CLOEXEC);
#endif

      r = posix_spawn_file_actions_adddup2 (&file_actions, read_null, 0);
      if (r != 0)
        goto out_close_fds;
    }

  if (stdout_fd >= 0)
    {
      r = posix_spawn_file_actions_adddup2 (&file_actions, stdout_fd, 1);
      if (r != 0)
        goto out_close_fds;

      if (!g_slist_find (child_close, GINT_TO_POINTER (stdout_fd)))
        child_close = g_slist_prepend (child_close, GINT_TO_POINTER (stdout_fd));
    }
  else if (stdout_to_null)
    {
      gint write_null = safe_open ("/dev/null", O_WRONLY | O_CLOEXEC);
      g_assert (write_null != -1);
      parent_close_fds[num_parent_close_fds++] = write_null;

#ifndef HAVE_O_CLOEXEC
      fcntl (write_null, F_SETFD, FD_CLOEXEC);
#endif

      r = posix_spawn_file_actions_adddup2 (&file_actions, write_null, 1);
      if (r != 0)
        goto out_close_fds;
    }

  if (stderr_fd >= 0)
    {
      r = posix_spawn_file_actions_adddup2 (&file_actions, stderr_fd, 2);
      if (r != 0)
        goto out_close_fds;

      if (!g_slist_find (child_close, GINT_TO_POINTER (stderr_fd)))
        child_close = g_slist_prepend (child_close, GINT_TO_POINTER (stderr_fd));
    }
  else if (stderr_to_null)
    {
      gint write_null = safe_open ("/dev/null", O_WRONLY | O_CLOEXEC);
      g_assert (write_null != -1);
      parent_close_fds[num_parent_close_fds++] = write_null;

#ifndef HAVE_O_CLOEXEC
      fcntl (write_null, F_SETFD, FD_CLOEXEC);
#endif

      r = posix_spawn_file_actions_adddup2 (&file_actions, write_null, 2);
      if (r != 0)
        goto out_close_fds;
    }

  /* If source_fds[i] != target_fds[i], we need to handle the case
   * where the user has specified, e.g., 5 -> 4, 4 -> 6. We do this
   * by duping the source fds, taking care to ensure the new fds are
   * larger than any target fd to avoid introducing new conflicts.
   *
   * If source_fds[i] == target_fds[i], then we just need to leak
   * the fd into the child process, which we *could* do by temporarily
   * unsetting CLOEXEC and then setting it again after we spawn if
   * it was originally set. POSIX requires that the addup2 action unset
   * CLOEXEC if source and target are identical, so you'd think doing it
   * manually wouldn't be needed, but unfortunately as of 2021 many
   * libcs still don't do so. Example nonconforming libcs:
   *  Bionic: https://android.googlesource.com/platform/bionic/+/f6e5b582604715729b09db3e36a7aeb8c24b36a4/libc/bionic/spawn.cpp#71
   *  uclibc-ng: https://cgit.uclibc-ng.org/cgi/cgit/uclibc-ng.git/tree/librt/spawn.c?id=7c36bcae09d66bbaa35cbb02253ae0556f42677e#n88
   *
   * Anyway, unsetting CLOEXEC ourselves would open a small race window
   * where the fd could be inherited into a child process if another
   * thread spawns something at the same time, because we have not
   * called fork() and are multithreaded here. This race is avoidable by
   * using dupfd_cloexec, which we already have to do to handle the
   * source_fds[i] != target_fds[i] case. So let's always do it!
   */

  for (i = 0; i < n_fds; i++)
    max_target_fd = MAX (max_target_fd, target_fds[i]);

  if (max_target_fd == G_MAXINT)
    goto out_close_fds;

  duped_source_fds = g_new (gint, n_fds);
  for (i = 0; i < n_fds; i++)
    {
      duped_source_fds[i] = dupfd_cloexec (source_fds[i], max_target_fd + 1);
      if (duped_source_fds[i] < 0)
        goto out_close_fds;
    }

  for (i = 0; i < n_fds; i++)
    {
      r = posix_spawn_file_actions_adddup2 (&file_actions, duped_source_fds[i], target_fds[i]);
      if (r != 0)
        goto out_close_fds;
    }

  /* Intentionally close the fds in the child as the last file action,
   * having been careful not to add the same fd to this list twice.
   *
   * This is important to allow (e.g.) for the same fd to be passed as stdout
   * and stderr (we must not close it before we have dupped it in both places,
   * and we must not attempt to close it twice).
   */
  for (elem = child_close; elem != NULL; elem = elem->next)
    {
      r = posix_spawn_file_actions_addclose (&file_actions,
                                             GPOINTER_TO_INT (elem->data));
      if (r != 0)
        goto out_close_fds;
    }

  argv_pass = file_and_argv_zero ? argv + 1 : argv;
  if (envp == NULL)
    envp = (const gchar * const *) environ;

  /* Don't search when it contains a slash. */
  if (!search_path || strchr (argv[0], '/') != NULL)
    r = posix_spawn (&pid, argv[0], &file_actions, &attr, (char * const *) argv_pass, (char * const *) envp);
  else
    r = posix_spawnp (&pid, argv[0], &file_actions, &attr, (char * const *) argv_pass, (char * const *) envp);

  if (r == 0 && child_pid != NULL)
    *child_pid = pid;

out_close_fds:
  for (i = 0; i < num_parent_close_fds; i++)
    close_and_invalidate (&parent_close_fds [i]);

  if (duped_source_fds != NULL)
    {
      for (i = 0; i < n_fds; i++)
        close_and_invalidate (&duped_source_fds[i]);
      g_free (duped_source_fds);
    }

  posix_spawn_file_actions_destroy (&file_actions);
out_free_spawnattr:
  posix_spawnattr_destroy (&attr);
  g_slist_free (child_close);

  return r;
}
#endif /* POSIX_SPAWN_AVAILABLE */

static gboolean
fork_exec (gboolean              intermediate_child,
           const gchar          *working_directory,
           const gchar * const  *argv,
           const gchar * const  *envp,
           gboolean              close_descriptors,
           gboolean              search_path,
           gboolean              search_path_from_envp,
           gboolean              stdout_to_null,
           gboolean              stderr_to_null,
           gboolean              child_inherits_stdin,
           gboolean              file_and_argv_zero,
           gboolean              cloexec_pipes,
           GSpawnChildSetupFunc  child_setup,
           gpointer              user_data,
           GPid                 *child_pid,
           gint                 *stdin_pipe_out,
           gint                 *stdout_pipe_out,
           gint                 *stderr_pipe_out,
           gint                  stdin_fd,
           gint                  stdout_fd,
           gint                  stderr_fd,
           const gint           *source_fds,
           const gint           *target_fds,
           gsize                 n_fds,
           GError              **error)
{
  GPid pid = -1;
  gint child_err_report_pipe[2] = { -1, -1 };
  gint child_pid_report_pipe[2] = { -1, -1 };
  guint pipe_flags = cloexec_pipes ? FD_CLOEXEC : 0;
  gint status;
  const gchar *chosen_search_path;
  gchar *search_path_buffer = NULL;
  gchar *search_path_buffer_heap = NULL;
  gsize search_path_buffer_len = 0;
  gchar **argv_buffer = NULL;
  gchar **argv_buffer_heap = NULL;
  gsize argv_buffer_len = 0;
  gint stdin_pipe[2] = { -1, -1 };
  gint stdout_pipe[2] = { -1, -1 };
  gint stderr_pipe[2] = { -1, -1 };
  gint child_close_fds[4] = { -1, -1, -1, -1 };
  gint n_child_close_fds = 0;
  gint *source_fds_copy = NULL;

  g_assert (argv != NULL && argv[0] != NULL);
  g_assert (stdin_pipe_out == NULL || stdin_fd < 0);
  g_assert (stdout_pipe_out == NULL || stdout_fd < 0);
  g_assert (stderr_pipe_out == NULL || stderr_fd < 0);

  /* If pipes have been requested, open them */
  if (stdin_pipe_out != NULL)
    {
      if (!g_unix_open_pipe (stdin_pipe, pipe_flags, error))
        goto cleanup_and_fail;
      if (_g_spawn_invalid_source_fd (stdin_pipe[0], source_fds, n_fds, error) ||
          _g_spawn_invalid_source_fd (stdin_pipe[1], source_fds, n_fds, error))
        goto cleanup_and_fail;
      child_close_fds[n_child_close_fds++] = stdin_pipe[1];
      stdin_fd = stdin_pipe[0];
    }

  if (stdout_pipe_out != NULL)
    {
      if (!g_unix_open_pipe (stdout_pipe, pipe_flags, error))
        goto cleanup_and_fail;
      if (_g_spawn_invalid_source_fd (stdout_pipe[0], source_fds, n_fds, error) ||
          _g_spawn_invalid_source_fd (stdout_pipe[1], source_fds, n_fds, error))
        goto cleanup_and_fail;
      child_close_fds[n_child_close_fds++] = stdout_pipe[0];
      stdout_fd = stdout_pipe[1];
    }

  if (stderr_pipe_out != NULL)
    {
      if (!g_unix_open_pipe (stderr_pipe, pipe_flags, error))
        goto cleanup_and_fail;
      if (_g_spawn_invalid_source_fd (stderr_pipe[0], source_fds, n_fds, error) ||
          _g_spawn_invalid_source_fd (stderr_pipe[1], source_fds, n_fds, error))
        goto cleanup_and_fail;
      child_close_fds[n_child_close_fds++] = stderr_pipe[0];
      stderr_fd = stderr_pipe[1];
    }

  child_close_fds[n_child_close_fds++] = -1;

#ifdef POSIX_SPAWN_AVAILABLE
  if (!intermediate_child && working_directory == NULL && !close_descriptors &&
      !search_path_from_envp && child_setup == NULL)
    {
      g_trace_mark (G_TRACE_CURRENT_TIME, 0,
                    "GLib", "posix_spawn",
                    "%s", argv[0]);

      status = do_posix_spawn (argv,
                               envp,
                               search_path,
                               stdout_to_null,
                               stderr_to_null,
                               child_inherits_stdin,
                               file_and_argv_zero,
                               child_pid,
                               child_close_fds,
                               stdin_fd,
                               stdout_fd,
                               stderr_fd,
                               source_fds,
                               target_fds,
                               n_fds);
      if (status == 0)
        goto success;

      if (status != ENOEXEC)
        {
          g_set_error (error,
                       G_SPAWN_ERROR,
                       G_SPAWN_ERROR_FAILED,
                       _("Failed to spawn child process “%s” (%s)"),
                       argv[0],
                       g_strerror (status));
          goto cleanup_and_fail;
       }

      /* posix_spawn is not intended to support script execution. It does in
       * some situations on some glibc versions, but that will be fixed.
       * So if it fails with ENOEXEC, we fall through to the regular
       * gspawn codepath so that script execution can be attempted,
       * per standard gspawn behaviour. */
      g_debug ("posix_spawn failed (ENOEXEC), fall back to regular gspawn");
    }
  else
    {
      g_trace_mark (G_TRACE_CURRENT_TIME, 0,
                    "GLib", "fork",
                    "posix_spawn avoided %s%s%s%s%s",
                    !intermediate_child ? "" : "(automatic reaping requested) ",
                    working_directory == NULL ? "" : "(workdir specified) ",
                    !close_descriptors ? "" : "(fd close requested) ",
                    !search_path_from_envp ? "" : "(using envp for search path) ",
                    child_setup == NULL ? "" : "(child_setup specified) ");
    }
#endif /* POSIX_SPAWN_AVAILABLE */

  /* Choose a search path. This has to be done before calling fork()
   * as getenv() isn’t async-signal-safe (see `man 7 signal-safety`). */
  chosen_search_path = NULL;
  if (search_path_from_envp)
    chosen_search_path = g_environ_getenv ((gchar **) envp, "PATH");
  if (search_path && chosen_search_path == NULL)
    chosen_search_path = g_getenv ("PATH");

  if ((search_path || search_path_from_envp) && chosen_search_path == NULL)
    {
      /* There is no 'PATH' in the environment.  The default
       * * search path in libc is the current directory followed by
       * * the path 'confstr' returns for '_CS_PATH'.
       * */

      /* In GLib we put . last, for security, and don't use the
       * * unportable confstr(); UNIX98 does not actually specify
       * * what to search if PATH is unset. POSIX may, dunno.
       * */

      chosen_search_path = "/bin:/usr/bin:.";
    }

  if (search_path || search_path_from_envp)
    g_assert (chosen_search_path != NULL);
  else
    g_assert (chosen_search_path == NULL);

  /* Allocate a buffer which the fork()ed child can use to assemble potential
   * paths for the binary to exec(), combining the argv[0] and elements from
   * the chosen_search_path. This can’t be done in the child because malloc()
   * (or alloca()) are not async-signal-safe (see `man 7 signal-safety`).
   *
   * Add 2 for the nul terminator and a leading `/`. */
  if (chosen_search_path != NULL)
    {
      search_path_buffer_len = strlen (chosen_search_path) + strlen (argv[0]) + 2;
      if (search_path_buffer_len < 4000)
        {
          /* Prefer small stack allocations to avoid valgrind leak warnings
           * in forked child. The 4000B cutoff is arbitrary. */
          search_path_buffer = g_alloca (search_path_buffer_len);
        }
      else
        {
          search_path_buffer_heap = g_malloc (search_path_buffer_len);
          search_path_buffer = search_path_buffer_heap;
        }
    }

  if (search_path || search_path_from_envp)
    g_assert (search_path_buffer != NULL);
  else
    g_assert (search_path_buffer == NULL);

  /* And allocate a buffer which is 2 elements longer than @argv, so that if
   * script_execute() has to be called later on, it can build a wrapper argv
   * array in this buffer. */
  argv_buffer_len = g_strv_length ((gchar **) argv) + 2;
  if (argv_buffer_len < 4000 / sizeof (gchar *))
    {
      /* Prefer small stack allocations to avoid valgrind leak warnings
       * in forked child. The 4000B cutoff is arbitrary. */
      argv_buffer = g_newa (gchar *, argv_buffer_len);
    }
  else
    {
      argv_buffer_heap = g_new (gchar *, argv_buffer_len);
      argv_buffer = argv_buffer_heap;
    }

  /* And one to hold a copy of @source_fds for later manipulation in do_exec(). */
  source_fds_copy = g_new (int, n_fds);
  if (n_fds > 0)
    memcpy (source_fds_copy, source_fds, sizeof (*source_fds) * n_fds);

  if (!g_unix_open_pipe (child_err_report_pipe, pipe_flags, error))
    goto cleanup_and_fail;
  if (_g_spawn_invalid_source_fd (child_err_report_pipe[0], source_fds, n_fds, error) ||
      _g_spawn_invalid_source_fd (child_err_report_pipe[1], source_fds, n_fds, error))
    goto cleanup_and_fail;

  if (intermediate_child)
    {
      if (!g_unix_open_pipe (child_pid_report_pipe, pipe_flags, error))
        goto cleanup_and_fail;
      if (_g_spawn_invalid_source_fd (child_pid_report_pipe[0], source_fds, n_fds, error) ||
          _g_spawn_invalid_source_fd (child_pid_report_pipe[1], source_fds, n_fds, error))
        goto cleanup_and_fail;
    }
  
  pid = fork ();

  if (pid < 0)
    {
      int errsv = errno;

      g_set_error (error,
                   G_SPAWN_ERROR,
                   G_SPAWN_ERROR_FORK,
                   _("Failed to fork (%s)"),
                   g_strerror (errsv));

      goto cleanup_and_fail;
    }
  else if (pid == 0)
    {
      /* Immediate child. This may or may not be the child that
       * actually execs the new process.
       */

      /* Reset some signal handlers that we may use */
      signal (SIGCHLD, SIG_DFL);
      signal (SIGINT, SIG_DFL);
      signal (SIGTERM, SIG_DFL);
      signal (SIGHUP, SIG_DFL);
      
      /* Be sure we crash if the parent exits
       * and we write to the err_report_pipe
       */
      signal (SIGPIPE, SIG_DFL);

      /* Close the parent's end of the pipes;
       * not needed in the close_descriptors case,
       * though
       */
      close_and_invalidate (&child_err_report_pipe[0]);
      close_and_invalidate (&child_pid_report_pipe[0]);
      if (child_close_fds[0] != -1)
        {
           int i = -1;
           while (child_close_fds[++i] != -1)
             close_and_invalidate (&child_close_fds[i]);
        }
      
      if (intermediate_child)
        {
          /* We need to fork an intermediate child that launches the
           * final child. The purpose of the intermediate child
           * is to exit, so we can waitpid() it immediately.
           * Then the grandchild will not become a zombie.
           */
          GPid grandchild_pid;

          grandchild_pid = fork ();

          if (grandchild_pid < 0)
            {
              /* report -1 as child PID */
              write_all (child_pid_report_pipe[1], &grandchild_pid,
                         sizeof(grandchild_pid));
              
              write_err_and_exit (child_err_report_pipe[1],
                                  CHILD_FORK_FAILED);              
            }
          else if (grandchild_pid == 0)
            {
              close_and_invalidate (&child_pid_report_pipe[1]);
              do_exec (child_err_report_pipe[1],
                       stdin_fd,
                       stdout_fd,
                       stderr_fd,
                       source_fds_copy,
                       target_fds,
                       n_fds,
                       working_directory,
                       argv,
                       argv_buffer,
                       argv_buffer_len,
                       envp,
                       close_descriptors,
                       chosen_search_path,
                       search_path_buffer,
                       search_path_buffer_len,
                       stdout_to_null,
                       stderr_to_null,
                       child_inherits_stdin,
                       file_and_argv_zero,
                       child_setup,
                       user_data);
            }
          else
            {
              write_all (child_pid_report_pipe[1], &grandchild_pid, sizeof(grandchild_pid));
              close_and_invalidate (&child_pid_report_pipe[1]);
              
              _exit (0);
            }
        }
      else
        {
          /* Just run the child.
           */

          do_exec (child_err_report_pipe[1],
                   stdin_fd,
                   stdout_fd,
                   stderr_fd,
                   source_fds_copy,
                   target_fds,
                   n_fds,
                   working_directory,
                   argv,
                   argv_buffer,
                   argv_buffer_len,
                   envp,
                   close_descriptors,
                   chosen_search_path,
                   search_path_buffer,
                   search_path_buffer_len,
                   stdout_to_null,
                   stderr_to_null,
                   child_inherits_stdin,
                   file_and_argv_zero,
                   child_setup,
                   user_data);
        }
    }
  else
    {
      /* Parent */
      
      gint buf[2];
      gint n_ints = 0;    

      /* Close the uncared-about ends of the pipes */
      close_and_invalidate (&child_err_report_pipe[1]);
      close_and_invalidate (&child_pid_report_pipe[1]);

      /* If we had an intermediate child, reap it */
      if (intermediate_child)
        {
        wait_again:
          if (waitpid (pid, &status, 0) < 0)
            {
              if (errno == EINTR)
                goto wait_again;
              else if (errno == ECHILD)
                ; /* do nothing, child already reaped */
              else
                g_warning ("waitpid() should not fail in 'fork_exec'");
            }
        }
      

      if (!read_ints (child_err_report_pipe[0],
                      buf, 2, &n_ints,
                      error))
        goto cleanup_and_fail;
        
      if (n_ints >= 2)
        {
          /* Error from the child. */

          switch (buf[0])
            {
            case CHILD_CHDIR_FAILED:
              g_set_error (error,
                           G_SPAWN_ERROR,
                           G_SPAWN_ERROR_CHDIR,
                           _("Failed to change to directory “%s” (%s)"),
                           working_directory,
                           g_strerror (buf[1]));

              break;
              
            case CHILD_EXEC_FAILED:
              g_set_error (error,
                           G_SPAWN_ERROR,
                           _g_spawn_exec_err_to_g_error (buf[1]),
                           _("Failed to execute child process “%s” (%s)"),
                           argv[0],
                           g_strerror (buf[1]));

              break;

            case CHILD_OPEN_FAILED:
              g_set_error (error,
                           G_SPAWN_ERROR,
                           G_SPAWN_ERROR_FAILED,
                           _("Failed to open file to remap file descriptor (%s)"),
                           g_strerror (buf[1]));
              break;

            case CHILD_DUPFD_FAILED:
              g_set_error (error,
                           G_SPAWN_ERROR,
                           G_SPAWN_ERROR_FAILED,
                           _("Failed to duplicate file descriptor for child process (%s)"),
                           g_strerror (buf[1]));

              break;

            case CHILD_FORK_FAILED:
              g_set_error (error,
                           G_SPAWN_ERROR,
                           G_SPAWN_ERROR_FORK,
                           _("Failed to fork child process (%s)"),
                           g_strerror (buf[1]));
              break;

            case CHILD_CLOSE_FAILED:
              g_set_error (error,
                           G_SPAWN_ERROR,
                           G_SPAWN_ERROR_FAILED,
                           _("Failed to close file descriptor for child process (%s)"),
                           g_strerror (buf[1]));
              break;

            default:
              g_set_error (error,
                           G_SPAWN_ERROR,
                           G_SPAWN_ERROR_FAILED,
                           _("Unknown error executing child process “%s”"),
                           argv[0]);
              break;
            }

          goto cleanup_and_fail;
        }

      /* Get child pid from intermediate child pipe. */
      if (intermediate_child)
        {
          n_ints = 0;
          
          if (!read_ints (child_pid_report_pipe[0],
                          buf, 1, &n_ints, error))
            goto cleanup_and_fail;

          if (n_ints < 1)
            {
              int errsv = errno;

              g_set_error (error,
                           G_SPAWN_ERROR,
                           G_SPAWN_ERROR_FAILED,
                           _("Failed to read enough data from child pid pipe (%s)"),
                           g_strerror (errsv));
              goto cleanup_and_fail;
            }
          else
            {
              /* we have the child pid */
              pid = buf[0];
            }
        }
      
      /* Success against all odds! return the information */
      close_and_invalidate (&child_err_report_pipe[0]);
      close_and_invalidate (&child_pid_report_pipe[0]);

      g_free (search_path_buffer_heap);
      g_free (argv_buffer_heap);
      g_free (source_fds_copy);

      if (child_pid)
        *child_pid = pid;

      goto success;
    }

success:
  /* Close the uncared-about ends of the pipes */
  close_and_invalidate (&stdin_pipe[0]);
  close_and_invalidate (&stdout_pipe[1]);
  close_and_invalidate (&stderr_pipe[1]);

  if (stdin_pipe_out != NULL)
    *stdin_pipe_out = g_steal_fd (&stdin_pipe[1]);

  if (stdout_pipe_out != NULL)
    *stdout_pipe_out = g_steal_fd (&stdout_pipe[0]);

  if (stderr_pipe_out != NULL)
    *stderr_pipe_out = g_steal_fd (&stderr_pipe[0]);

  return TRUE;

 cleanup_and_fail:

  /* There was an error from the Child, reap the child to avoid it being
     a zombie.
   */

  if (pid > 0)
  {
    wait_failed:
     if (waitpid (pid, NULL, 0) < 0)
       {
          if (errno == EINTR)
            goto wait_failed;
          else if (errno == ECHILD)
            ; /* do nothing, child already reaped */
          else
            g_warning ("waitpid() should not fail in 'fork_exec'");
       }
   }

  close_and_invalidate (&stdin_pipe[0]);
  close_and_invalidate (&stdin_pipe[1]);
  close_and_invalidate (&stdout_pipe[0]);
  close_and_invalidate (&stdout_pipe[1]);
  close_and_invalidate (&stderr_pipe[0]);
  close_and_invalidate (&stderr_pipe[1]);

  close_and_invalidate (&child_err_report_pipe[0]);
  close_and_invalidate (&child_err_report_pipe[1]);
  close_and_invalidate (&child_pid_report_pipe[0]);
  close_and_invalidate (&child_pid_report_pipe[1]);

  g_clear_pointer (&search_path_buffer_heap, g_free);
  g_clear_pointer (&argv_buffer_heap, g_free);
  g_clear_pointer (&source_fds_copy, g_free);

  return FALSE;
}

/* Based on execvp from GNU C Library */

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)) until it calls exec(). */
static gboolean
script_execute (const gchar *file,
                gchar      **argv,
                gchar      **argv_buffer,
                gsize        argv_buffer_len,
                gchar      **envp)
{
  /* Count the arguments.  */
  gsize argc = 0;
  while (argv[argc])
    ++argc;

  /* Construct an argument list for the shell. */
  if (argc + 2 > argv_buffer_len)
    return FALSE;

  argv_buffer[0] = (char *) "/bin/sh";
  argv_buffer[1] = (char *) file;
  while (argc > 0)
    {
      argv_buffer[argc + 1] = argv[argc];
      --argc;
    }

  /* Execute the shell. */
  if (envp)
    execve (argv_buffer[0], argv_buffer, envp);
  else
    execv (argv_buffer[0], argv_buffer);

  return TRUE;
}

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)). */
static gchar*
my_strchrnul (const gchar *str, gchar c)
{
  gchar *p = (gchar*) str;
  while (*p && (*p != c))
    ++p;

  return p;
}

/* This function is called between fork() and exec() and hence must be
 * async-signal-safe (see signal-safety(7)) until it calls exec(). */
static gint
g_execute (const gchar  *file,
           gchar       **argv,
           gchar       **argv_buffer,
           gsize         argv_buffer_len,
           gchar       **envp,
           const gchar  *search_path,
           gchar        *search_path_buffer,
           gsize         search_path_buffer_len)
{
  if (file == NULL || *file == '\0')
    {
      /* We check the simple case first. */
      errno = ENOENT;
      return -1;
    }

  if (search_path == NULL || strchr (file, '/') != NULL)
    {
      /* Don't search when it contains a slash. */
      if (envp)
        execve (file, argv, envp);
      else
        execv (file, argv);
      
      if (errno == ENOEXEC &&
          !script_execute (file, argv, argv_buffer, argv_buffer_len, envp))
        {
          errno = ENOMEM;
          return -1;
        }
    }
  else
    {
      gboolean got_eacces = 0;
      const gchar *path, *p;
      gchar *name;
      gsize len;
      gsize pathlen;

      path = search_path;
      len = strlen (file) + 1;
      pathlen = strlen (path);
      name = search_path_buffer;

      if (search_path_buffer_len < pathlen + len + 1)
        {
          errno = ENOMEM;
          return -1;
        }

      /* Copy the file name at the top, including '\0'  */
      memcpy (name + pathlen + 1, file, len);
      name = name + pathlen;
      /* And add the slash before the filename  */
      *name = '/';

      p = path;
      do
	{
	  char *startp;

	  path = p;
	  p = my_strchrnul (path, ':');

	  if (p == path)
	    /* Two adjacent colons, or a colon at the beginning or the end
             * of 'PATH' means to search the current directory.
             */
	    startp = name + 1;
	  else
	    startp = memcpy (name - (p - path), path, p - path);

	  /* Try to execute this name.  If it works, execv will not return.  */
          if (envp)
            execve (startp, argv, envp);
          else
            execv (startp, argv);
          
          if (errno == ENOEXEC &&
              !script_execute (startp, argv, argv_buffer, argv_buffer_len, envp))
            {
              errno = ENOMEM;
              return -1;
            }

	  switch (errno)
	    {
	    case EACCES:
	      /* Record the we got a 'Permission denied' error.  If we end
               * up finding no executable we can use, we want to diagnose
               * that we did find one but were denied access.
               */
	      got_eacces = TRUE;

              G_GNUC_FALLTHROUGH;
	    case ENOENT:
#ifdef ESTALE
	    case ESTALE:
#endif
#ifdef ENOTDIR
	    case ENOTDIR:
#endif
	      /* Those errors indicate the file is missing or not executable
               * by us, in which case we want to just try the next path
               * directory.
               */
	      break;

	    case ENODEV:
	    case ETIMEDOUT:
	      /* Some strange filesystems like AFS return even
	       * stranger error numbers.  They cannot reasonably mean anything
	       * else so ignore those, too.
	       */
	      break;

	    default:
	      /* Some other error means we found an executable file, but
               * something went wrong executing it; return the error to our
               * caller.
               */
	      return -1;
	    }
	}
      while (*p++ != '\0');

      /* We tried every element and none of them worked.  */
      if (got_eacces)
	/* At least one failure was due to permissions, so report that
         * error.
         */
        errno = EACCES;
    }

  /* Return the error from the last attempt (probably ENOENT).  */
  return -1;
}

/**
 * g_spawn_close_pid:
 * @pid: The process reference to close
 *
 * On some platforms, notably Windows, the #GPid type represents a resource
 * which must be closed to prevent resource leaking. g_spawn_close_pid()
 * is provided for this purpose. It should be used on all platforms, even
 * though it doesn't do anything under UNIX.
 **/
void
g_spawn_close_pid (GPid pid)
{
}